DE1799009B1 - DATA PROCESSING AND DISPLAY DEVICE - Google Patents

Description

The invention relates to a data processing and display device with a cathode ray tube with a display lane grid having a series of parallel lanes that are several generally rectangular Cover areas for the display of characters, with a character generator and with a scanning pulse generator, to sample the binary coded signals present at the character generator and to give synchronous with the display track grid on the cathode ray tube to selectively at predetermined Dots along each display track corresponding to the binary coded signals being sampled to increase the intensity of the cathode ray to display a desired character.

From the reference "Zeitschrift: ELECTRONICS", May 1953, pages 200, 202-204, is already a magnetic core matrix known in which predetermined cores are premagnetized, which are already in the Core matrix are arranged in the order of the digit or letter to be displayed. the Magnetic core matrix is then as with the scanning of the cathode ray tube screen with the aid of a Electron beam is scanned line by line or column by column, the premagnetized nuclei each at emit a signal when they are scanned. A reading wire is drawn through all magnetic cores through which the the signal emitted by the relevant magnetic core is read. The signal obtained becomes an amplification or attenuation of the electron beam scanning the cathode ray tube screen related, which altogether changes the representation already latent in the magnetic core memory one digit. The disadvantage of this arrangement is that a relatively expensive memory is required is that at a relatively high speed, namely the scanning speed of the Cathode ray tube, must be scanned.

The present invention is now based on the object of providing a simply structured data processing and display device,

with a variety of alphanumeric characters in different character sizes on a cathode ray tube can be displayed.

This task is based on a data processing and display device of the introduction mentioned type solved according to the invention as indicated in claim 1. With the data processing according to the invention and display device is given in a simple manner the possibility to hand the same alphanumeric characters in both a large and a small character representation on the cathode ray tube display. An extremely simple control makes this easy the representation of fractions is possible with the individual characters shown in small character representation must appear in different positions in their field of vision.

Preferably further refinements of the invention emerge from the subclaims.

In the following, the invention will be described in more detail with reference to preferred exemplary embodiments shown in the drawing explained. It shows

Fig. 1 is an enlarged view showing schematically how the alphabetical and numerical Symbols are generated on the screen of the cathode ray tube, and

Fig. 2 is a block diagram of the control circuit for generating alphabetic and numeric Symbols on the screen of the cathode ray tube.

According to Fig. 1, the electron beam of the cathode ray tube 28 is deflected so that a certain Raster pattern is generated. The format of the data display consists of 4 lines of characters, where each line contains up to 6 characters. The raster pattern that is created on the screen of the cathode ray tube appears in the form of 4 parallel grids that extend across the face of the tube. Each of the 4 grids has a height that is comparable to the height of the characters. The beam of the CRT is deflected to a generally sawtooth-shaped track across the face of the tube at each of 4 rasters, with the "up" bars representing the data and the "down" bars representing the Trailing lines are. At the end of the 1st, 2nd and 3rd line, the ray becomes the beginning of the next one Line distracted. At the end of the 4th line, the beam is deflected to the starting position of the 1st line.

In operation, both the "up" and "down" bars of the track are normal blanked in such a way that no visible traces appear on the tube screen. The characters appear on the tube screen by optionally exciting predetermined parts of certain "up" strokes will. For this purpose, each "up" stroke can be divided into 7 consecutive segments or elements are viewed as subdivided. Since each of these elements has an exact timing along the Radiation line occupies, the beam can be amplified by suitable signaling devices so that on the tubular screen a visible point at selected locations of the elements or segments of the selected "Up" dashes appear. In the display format shown, 5 form adjacent "Up" dashes the area in which each character is formed.

Thus, each character appears in the form of a 5 X 7 matrix. Between every group of 5 that the Form the area in which each character is formed, there is an additional "upward" line. This additional "Up" bar remains in his, with one exception to be described below blanked state, so that a space remains between adjacent characters. The Indian The letter "B" shown in the upper left corner in FIG. B. generated in that all 7 elements of the first outward run or the "upward" dash, the 1st, 4th and 7th element of each outward run 2—4 and the 2nd, 3rd, 5th and 6th elements of the 5th outward run are amplified or displayed.

In order to be able to display fractions (or decimals, minutes, etc.), special facilities are provided, to form the characters using a code that merely reinforces elements that are in a body part of the basic character area, as shown in lines 2-4 of FIG. With the present Embodiment, this part comprises only 4 of the free 5 available vertical runs and only 5 of the available 7 amplifiable or illuminable elements of each "up" bar. With others Words, a 4 X 5 element matrix is selected from the 5 X 7 primitive matrix, and in this smaller matrix becomes a correspondingly smaller character for the special purpose required displayed. The smaller 4 X 5 area is essentially "similar" to the 5 X 7 base area; H. the Ratio of the lengths of the short and long sides is approximately the same and the angles are the same, so that the representation of the smaller characters is the same as the representation of the larger characters. If those If smaller characters are used to indicate fractions, the break line will be between the counter and the denominator is generated by removing all 7 elements of the normally blanked "up" bar becomes enlightened between the signs.

As can be seen from Fig. 2, from a memory 58, which z. B. can exist in the form of a cyclically actuated delay line, with the help of a logic element controlled by a clock pulse sequence T 150 data, which for example consist of 5 basic data bits and an additional bit, retrieved from the memory. The 6 bits belonging to a data item are fed one after the other to a register 152, from where they are shifted in parallel to a second register 154.

From register 154, four data bits are fed directly to a character generator 156 which is suitable is to generate signals to control the display on each CRT. A certain data bit is on a "Small Character Control Circuit" represented by block 158 is directed. This circuit causes that the character generator sends a signal to develop a character for the small representation in 4 X 5 matrix generated.

The character generator 156 includes a conventional array of diodes and associated circuitry for converting a used permutation code signal with six data bits into a corresponding one Permutation code signal with basically 48 data bits. Of these 48 data bits, thirty-five are required to build a 5 X 7 display matrix for large symbols, seven more are for the unmarked ones vertical scanning track is required, which forms the spaces between the characters, and the remaining six bits are provided for the flyback time of the six vertical scan tracks for each Sign. When a small sign with a

4 X 5 matrix is to be displayed, then only twenty character bits instead of thirty-five character bits intended for representation even when the small character is used as part of a fraction will. In this last case, seven additional bits are required to represent a vertical line, to show a fraction line between the numerator and denominator.

The forty-eight bit signal developed by the character generator appears on forty-eight separate output conductors connected to a conventional translator 166. This converter is driven by a clock 170 via a line 168 and converts the generated parallel forty-eight bit code signal into a corresponding forty-eight bit row signal. The individual pulses of this series signal run at the frequency of the clock generator, which in the present exemplary embodiment operates at a frequency of 1070 kHz. This frequency is related to the scan track frequency of the CRT display units 28 (one scan track corresponding to a column of 7 bits in a mapping matrix of 5X7) that forty-eight clock pulses occur during the time the CRT is recording each complete character through scan tracks. Thus, it will be apparent that the forty-eight bit line signal generated by the translator is capable of forming the characters by intensifying the CRT beam at predetermined points to produce the outline of any desired character.

Assuming first the case where the forty-eight bit line signal is for a large 5X7 character, the output of converter 166 is provided on line 172 and gate 174 to a common video line 176 .

When the CRT is to be put into operation, the positive voltage from the relevant first Line taken. As a result, switching means are switched on at the station in question to the vertical and horizontal deflection tracks to start the CRT. The first forty-eight bit row code signal for the CRT, the video line is applied essentially simultaneously, in the form of negative directional signals to intensify the CRT beam to produce the desired dot pattern. As soon as the end of all seven data bits is reached, i. H. at the top of each vertical scan track, a positive voltage is applied to the video cable for only the short period of time of the next (eighth) data bit. This positive tension brings the vertical strip to its original position back, so that the process is again with fixed synchronization with the next group with seven data bits begins. However, this positive voltage has no effect on the horizontal scanning track, which continues to move sideways over the CRT's display area.

When the end of the first line is reached, i.e. H. after six characters with 48 bits each have been transmitted, again a positive voltage is applied to the corresponding cable, but this time for the Eight bit duration. This longer time signal is generated by a suitable integrating circuit in the station detects and causes the horizontal scanning track to be reset for the beginning of the sequence the next horizontal scan track. It should be noted that the duration of this synchronizing signal of eight bits takes up all of the time during which the first "empty" vertical scan track normally occurs and it follows that the first character has only five vertical scanning tracks and not six, like the remaining characters. The same five-track arrangement is used for all The first character on all four lines is used to ensure vertical alignment of the characters. Although a forty-eight bit signal is used for the indicator, usually only thirty-five elements to be controlled interchangeably. So the character generator and the Converters advantageously correspond to a set of thirty-five AND gates with two inputs the thirty-five possible point positions on the CRT. The outputs of these links are over OR circuits are interconnected and form a combined output. An input signal each AND element is a converter pulse, of which there is a set of thirty-five pieces, which occur one after the other at suitable time intervals. The second output of each AND element causes a special point position through the character | B it is requested which one should be displayed. ^^ Only the common video output and the converter gates have to work at a higher frequency.

The device also includes devices for controlling the position of the small 4 X 5 matrix characters, depending on whether these characters are to appear as fraction counters, fractional denominators, decimals, and so on. This position is controlled by a special data bit. The presence of such a data bit is determined by a detector which receives its input signal from a stage 155 of the storage register 154. If, for example, the fact whether it is a large or a small matrix character is determined in each case by the bit in the third position in a data, then if such a data bit is present that indicates the presence of a small matrix character, this fact is indicated by a Flip-flop 192 detected, which is set during the time that every third bit is entering register 154. The resulting setting of this flip-flop operates a line 194 which controls the gate 174 g * in such a way that its input line 172 is blocked ^ J (which is used for the representation of large symbols), and another input line 196 opens which is connected to data line 172 via a 10-bit delay line 198 which is synchronized via line 168 from the clock generator.

Thus, the 48-bit row code signal corresponding to the delay line character in register 154 is delayed 10 bits in its transmission to its CRT display. It can be seen that this delay causes the small 4 X 5 matrix number to be shifted from its normal location in the lower left corner of the larger 5 X 7 character area to the upper right corner of that area, ie, in the manner that it does 1 in line 3, position 3 of the CRT display can be seen.

Flip-flop 192 forms part of an actual shift register, and when the timing signal for the next character occurs, flip-flop 192 sets another flip-flop 200 and is itself reset at the same time. By setting the flip-flop 200 , a line 202 is applied, which closes the member 174 and this member to another line

204 opens. This latter line is connected to the second stage of the delay line 198 , so that the 48-bit character which is thereby given to the gate 174 is delayed by two bits. This two-bit delay, in turn, places the small number in the top left corner of the 5 X 7 matrix area, e.g. B. the number "3" in position 4 of line 3 in FIG.

When the next character occurs, flip-flop 200 resets itself, sets another flip-flop 206 and operates a fraction generator 208. This latter circuit includes means for supplying gate 174 with a signal which is used for the first seven points to mark the first vertical scanning track of the next character (in this case position no. 5). This creates a fraction line that separates the numerator and denominator. The flip-flop 206 acts on a line 210 which controls the element 174 in such a way that the 48-bit character signal which arrives via the line 212 from the eighth stage of the delay line 198 is applied to this element. Thus, the small number in position no. 5 is shifted to the right with an 8-bit delay by a distance from a vertical scanning track, so that this symbol occupies the lower right corner of the large 5x7 matrix area.

When the next character is introduced into the register 154 , the flip-flop 206 is reset, so that the gate 174 is directly ready for data from the basic data line 172 , ie without delay. Thus, the sixth small number symbol is brought into its normal position in the lower left corner of the larger 5 X 7 matrix area, ie in position 6 of line 3 in FIG Digits 5 and 6 can be either 16 or 32, depending on whether the effects are traded in sixteenths or thirty-second notes.

If the bit of the fourth character position of any CRT line is marked, which indicates a double decimal answer, then this character is detected by a flip-flop 214 which is connected to the stage 155 of the register 154 . At this point in time, the flip-flop 214 does not trigger any actuation, but this flip-flop resets itself at the time of the next character and at the same time sets the flip-flop 206. This moves the small 4X5 number character in the lower right corner of the huge

5 X 7 matrix area set in position No. 5 of the CRT; H. the result is a display like the one in Line 4 of Fig. 1 is shown. The next small character (for position no. 6) is not delayed and it is therefore in the lower left corner immediately next to (but vertically through a perpendicular Scanning track separated) the small number sign is set in position no.5. This arrangement shows that Observer that the numbers in the positions 5 and

6 are to be regarded as decimals, i.e. H. as tenths and hundredths.

If the bit of the fifth character position of any line 2 to 4 is marked, which indicates an answer in eighths of a fraction, then this is detected by the flip-flop 200 , the setting of which in the manner described above causes a dash between the fifth and sixth Position in the CRT display and which also causes the 48-bit code signal for position number 5 to be delayed by two bits. This delay causes the small number character to move to the upper left position, e.g. B. moved to line 2 of FIG. The flip-flop 206 is then set for the next symbol (a small "*"), and the resulting eight-bit delay causes this symbol to be in the lower right corner. of the 5 X 7 matrix area shifted e.g. B. as shown in position no. 6 in line 2 of FIG.

For this purpose 2 sheets of drawings 709539/41

Claims (6)

Patent claims: 1. Data processing and display device with a cathode ray tube with a display lane grid with a series of parallel tracks which cover a plurality of generally rectangular areas for the display of characters, with a character generator and with a sampling pulse generator to sample the binary coded signals present at the character generator and synchronously with the display track grid on the cathode ray tube in order to selectively amplify the intensity of the cathode ray at predetermined points along each display track in accordance with the scanned binary coded signals for displaying a desired character, characterized in that a receiving device (152) for receiving a binary signal, which contains information about a large or small representation of a character transmitted thereby, it is provided that a decoder (158) is provided for determining the information about the size of the representation of the character, that the vo n the signal received from the decoder (158) is applied to the character generator (156) , and that the binary signal given by the receiving device (152) to the character generator (156) is converted into a set of binary-coded output signals as a function of the signal received from the decoder is implemented, which when displayed on the cathode ray tube (20) either form a character in a large representation or in a reduced representation. 2. Apparatus according to claim 1, characterized in that the image area for a large Character representation is determined by a 5 X 7 display track dot matrix and that the image area intended for a small character display by a 4 X 5 display track dot matrix is. 3. Apparatus according to claim 1 or 2, characterized in that the display tracks run vertically and form a series of adjacent image areas in which several characters can be displayed, and that at least one additional track is provided between adjacent image areas, and that devices (208 ) are provided in order to form all points along an additional track between two adjacent E 'image areas to form a fraction line between two character displays in a small character representation. 4. Device according to one of the preceding claims, characterized in that delay devices (198) are connected between the output of the character forming device (156, 166) and the input of the cathode ray tubes (CRT) in order to delay the display of the coded pulses given to the cathode ray tube and in that control means (192,200,206) are provided to control the amount of delay introduced by said delay means (198) for setting the characters to be displayed in the rectangular character area so that two successive small characters result in a fraction the first small character in the upper left corner of the normal drawing area and the second small one Character is moved to the lower right corner of a normal drawing area. 5. Apparatus according to claim 4, characterized in that the delay device (198) can be controlled with the aid of the time-controlled control devices (192, 200, 206) in such a way that a delay of 10, 2, 8 or 0 pulses takes place in successive character representations, whereby successive characters in positions for the display of sixteenths or thirty-second notes can be represented numerically. 6. Device according to one of the preceding claims, characterized in that a timer device (170) is provided for actuating the scanning track grid, and that responsive to the timer device means (174) are provided to the transmitted to the cathode ray tube code pulse signals according to the position, the the sign on the cathode ray tube is supposed to take control.