DE2541744C2 - Arrangement for rendering characters - Google Patents

Description

The invention relates to an arrangement according to the preamble of claim i.

Such a device is known from DE-OS 47 532. Moving part of a Line of characters takes place in that the circular memory according to FIG. 6 of this publication has three outputs, which are separated from each other by a register, in which the information is in each case a single Character can be saved. As stated at the end of the description of the above-mentioned document, can also increase the capacity of the circular buffer memory line by line by one character at a time will. In any case, however, additional outputs are required on the circulating accumulators. Furthermore is not specified in detail in the above-mentioned publication, such as the transfer of the shifted line of characters from the circular buffer is to take place in the circular buffer, so that the shifted line can be displayed repeatedly below.

It is the object of the invention. to specify an arrangement of the type mentioned, in which with low Overhead and without additional connections, the circular memory shifted part of a line of characters and the line moved in this way in the circular buffer

can be saved.

This object is achieved according to the invention by what is stated in the characterizing part of claim 1 Features solved. The line of text is only shifted by means of a corresponding clock control of the circulating memory compared to the circulating buffer memory, so that no additional outputs of the Circulating storage is required. The circulation memory can therefore consist of a single integrated shift register. The cursor symbol generator is on known, but as a result of the fact that the entrance the buffer memory can be selectively controlled instead of the input of the circular memory, a simplification obtain. It is known to use the buffer memory at a relatively low operating frequency, thus, depending on the technology used, greater or less protection against interference Energy consumption is achieved. This also means that the input device at a lower Frequency can work, which can make it cheaper than what is usually slow-working electronic Devices is inherent.

It is useful if the buffer memory is designed as a shift register. Such is the tolerance of occurrence of the various signals is low and the synchronization is stable in relation to disruptive influences.

The invention is explained in more detail below, for example with reference to the drawing. It shows
F i g. 1 shows a block diagram of a memory module according to the prior art,

Fig.2 is a block diagram of a combination of a Circulating storage and a buffer storage.

F i g. 3 is a block diagram of a position indicator symbol generator and

F i g. 4 is a block diagram of a device according to the invention.

F i g. 1 shows a block diagram of a memory module according to the state of the art cited above. Information is entered via line 2 and the Output via terminal 4. A logical »I« signal at control terminal 1 can be sent by the logical AND gate Unlock 7: a logical "O" signal unlocks the logical AND gate 6 via the inverter 5 Terminal 3 clock pulses can be received, ile-

ren frequency depends on the transmission characteristics of the delay line 12 is adapted. The converter 14 matches the clock pulses to the input and output flip-flops used 9, 15 and the modulator 10. In this example the modulator is an AND gate, with Help information in the form of amplitude modulation can be deleted. Items 11 and 13 are Kegeneration Booster. The circulating memory can according to FIG. 1, which also applies to the buffer memory is the case, in which case, however, the capacity of the line 12 is sufficient for several lines of information got to. The delay line 12 can be subdivided if / u is of great length, each part can also be divided be provided with additional regeneration members. The parts can also be configured as a parallel circuit be.

Fig. 2 shows a block diagram of a combination of a circular memory and a buffer memory. In this For example, the buffer memory consists of three in Rci hc switched modules according to FIG. I (26, 27, 28). the Via a Teüerschallung 36 part of the impulses son the clock 35 received. The clock 55 sieucrt the shift register 34 directly. whereby .in its Output 37 the information of the moment

The character to be mapped appears synchronously with the scanning stroke of the electron beam in a picture tube Output 37 must then also be connected to a signal input of a picture tube. To depict a Line of characters are e.g. B. eight lines of image required. As a result, the information from the shift register is just as often 34 fed back via gates 31 and 32 between two successive lines of characters the information from one of the modules 26, 27, 28 is sent to the shift register 34 via the gates 30 and 32 forwarded. The modules 26, 27 and 28 can operate at a slower speed than the shift register 34 work as several, e.g. B.? £ ht, space lines shown must be taken while the information is extracted from a module During the mapping of gap lines the gate 30 is permeable, thereby reducing the output of the buffer memory during this Time is connected to the input of the circulating memory (34). To get a proper fit, The shift register 34 receives a lower value from the clock generator 35 during the interval lines Clock pulse frequency. During the mapping of image lines with character information, the gate 35 is open. In addition, the modules 26, 27, 28 are fed back into themselves, but this is not shown separately. Now there are two options. The first is that when mapping a space the gate 23 is also open. In this case, the circuit shown is suitable for mapping three lines of characters, whereby the entire information unit is always present in the modules 26, 27, 28: in the Mapping a space, the information in a line of characters is always shifted across a module. At the beginning of the mapping of an image grid, the information is always available in the starting position. During the imaging of an image grid, the information in the modules 26, 27, 28 can be one or one circulate a whole number of times.

A second possibility is that the input of the logical AND gate 23 is not connected to the output of the module 28. but is connected to terminal 37. This creates a feedback circuit with a total capacitance obtained from four lines of text. Incidentally, the same effect applies as above. The whole is controlled by de / control unit 29, which the Clock generator 35 starts and controls and the gates 22, 23, 30, 31 optionally opens via the inverters 25, 33, further, appropriately, the return time between successive image lines and between successive scans of the entire image raster is taken into account. New information can be written in via terminal 21. This character information can always consist of z. B. consist of six bits; these six bits can then be used in the gates and memory modules can be processed in series. Others ksnn the information can always be processed in parallel. In this case, gates, supply lines and the like must be designed six times.

F i g. 3 shows a block diagram of an A.y position indicator / eigesymbolenener including other parts of an imaging device according to the aforementioned prior art. The clock pulse generator 40 controls the memory modules and drives a counter chain, which consists of the bit / iihlcr 41. which counts the number of bits per character, a Character counter 42 that counts the number of characters per line, a line counter 43 that counts the number of picture lines i only one line of characters (including the interim: iiimi'O counts, and a line counter 44 which counts the number of lines per picture. These counters are decoded; in step 45 the horizontal and in step 46 the vertical synchronization and Readout pulses generated. Characters can be transferred to the buffer memory 48 via the input / output stage 47 via the communication line 49 or via the keyboard 50. The location in which to save is marked on the screen by the position display information and can be accessed using the keyboard 50

ίο or from the one connected to the communication line 49 Computing system via the input / output stage 47 by means of two counters, namely the horizontal position display symbol counter 51 and the vertical cursor symbol counter 52 are selected. These are compared with the positions of the named counters 42, 43, 44 via the comparison circuits 53, 54, 55. The mapping of the position indicator information on the screen occurs when the positions of the position indicator symbol counters 51 and 52 are the same as the positions of the counters 42 and 44, respectively, which is indicated by the comparison circuits 53 or 55 is indicated; the outputs of the two circuits are connected to one another by the logical AND gate 56 tied together; this gate emits a signal. when the electron beam passes the point on the screen that corresponds to the positions of the counters 51 and 52. The comparison circuits 53 and 54 compare the positions of Elements 42 and 51 or 43 and 52; their output signals are combined by the logical AND gate 57, and the latter again controls the supply of data by means of the keyboard or the computer system to the image memory 48. This is possible because the character counter 42 rotates synchronously with the memory modules, if the number of character lines per image is equal to the number of image lines per character line or z. B. is two or four times larger.

The line-by-line transfer of the stored information from the buffer memory 48 to the circular memory 58 for one line is controlled by the direction 59 Steuervoi. This is done according to the locations of the Counters 43, 44, which are decoded by the decoders 60 and 61. The information circulating in the circulating memory 58 is fed to the character generator 62. The character generator 62 also receives from the decoder 60 the information which image line of the character line must be exactly mapped while he is a Emits an image signal which corresponds to the point grid of the character to be imaged and which in the mixer 63 is mixed with the synchronization and readout signals of the aforementioned stages 45 and 46. The output signal appears at terminal 64 and wildly the signal input of a television monitor, not shown fed. The illustration of the position indicator infcmiiiion can be done in a suitable manner by the fact that the stage 65 inverts the image signal during the time in which the electron beam passes the point to be marked.

4 shows a block diagram of a device according to the invention. The device includes control input terminals 80, 8Ü / 4, 82, an information output terminal 81, a signal output terminal 83. an input device 84, a multiplexing device 85. a buffer memory 86, a decoder 87. a multiplexing device 88, a circulating memory 89. a space information input line 90. a character information transport line 91, a clock control input 92, a clock pulse generator 93, a distributor circuit 94, a clock pulse line 95, a clock pulse line 96, a control input 97, an information

tiun input 98, a horizontal position indicator symbol generator 99, a vertical position indicator symbol generator 100, logical AND gates _{1Ot 1} iO3, 105, 107 and bistable elements 102, 104, 106, 108.

The buffer memory 86 can store the information of all lines of characters to be imaged. An output of the same is connected to the input of the circular memory 89 via the multiplexing device 88. The output of the latter memory is optionally connected via a signal generator and other devices, such as amplifiers, to a television monitor (not shown) for displaying the information, to the second input of the multiplexing device 88 and to an input of the multiplexing device 85. The clock pulse generator 93 is controlled by signals at the terminal 92. The output of the buffer memory 86 is also connected to an input of the multiplexing device 85 and to the output terminal 81. By means of the input device 84 , character information can be conveyed via the line 91 and space information via the line 90 to the multiplexing device 85 . When an image line is mapped with character information, the multiplexing devices 85, 88 are controlled by signals at inputs 82, 97 in such a way that the memories are fed back into themselves. The multiplex device 85 receives a second-bit signal from the decoder 87. the multiplex device 88 a one-bit signal via the control input 97. The clock pulse generator 93 outputs clock pulses via the distribution circuit 94 via the lines 95 and 96 to the buffer memory 86 and the circular memory 89, both of which are designed as shift registers. As described above, sometimes the buffer memory can be operated at a slower speed; for the time being it is assumed that this is not the case. When mapping a gap line, the multiplexing device 88 receives a signal via the control terminal 97, with the aid of which the information of a line of characters is transferred to the circular memory, while the information is fed back in the buffer memory 86 and returns to the input via the multiplexer 85 and is shifted by one line. The relevant special information is fed to the decoder 87 via terminal 82. The horizontal position indicator symbol generator 99 and the vertical position indicator symbol generator 100 give, as in the circuit according to FIG. 3. Signals to an element connected to the output of the circulating memory 89, not shown in detail, which corresponds to the element 65 according to FIG. 3, from which the special symbol display information is mapped. So far, the mode of operation of the circuit corresponds to that of the previous figures.

The circuit can perform two more operations, namely:

a) the "insert" of a character,

b) the deletion ("delete") of a character in each case from the special position display information specified place.

When a character is inserted, the relevant information is fed to the input device 84 via the input 98. It is still assumed that the image lines are scanned in the direction of normal reading, in the case of the Latin script, aiso from left to right.

At the terminal 80 the signal "insert character" appears as an impulse which puts the bistable element 102 in the "!" Position. This signal can be /. I). be directly linked to pressing an information key on a keyboard. The character can also be a space character. Under the control of the "!" Position and the corresponding signal of the horizontal Pum tion display symbol generator 99, the bistable element 104 is placed in the "1" position via the logical AND gate 103. Under the control of this position, one or more T.iki pulses are withheld from the circulating memory 89, as a result of which the information contained therein about a character position "lags". This can advantageously take place at the beginning of the mapping a number of space lines between two lines, so that on the one hand the mapping is not influenced and on the other hand the information is transferred from the buffer memory in the usual way.

Under the control of the output signal of the bistable element iO2 and the corresponding signal of the horizontal position indicator symbol generator 99 and of the vertical position indicator symbol generator 100 , the decoder 87 is controlled via the logical AND gate 101 in the following way: During a drawing period, the line 91 is connected to the buffer memory 86 tied together; beginning with the subsequent / ei chenpriode, the output of the recirculating memory 89 is fed back via the multiplexing device 85 , so that the shifted characters are now stored in the buffer memory. In addition, the bistable elements 102, 104 are reset to the zero position, possibly with a slight delay. At the end of the space, the entered character and the characters already stored are stored in the correct location for mapping in the buffer memory 86 .

When a character is deleted, a control pulse appears at terminal vüA, which enables bistable learning; 'Often put in the "!" Position. Under the control of this "!" Position and the correspondence signal of the horizontal position indicator symbol generator 99, the bistable element 108 is placed in the "!" Position via the logical AND gate 107. Under the control of this position, one or more additional clock pulses are supplied from the distribution circuit 94 to the circulating memory 89, whereby the information therein "leads" over one or more characters. Again, this can advantageously take place at the beginning of the mapping of a number of gap lines.
Under the control of the output signal of the bistable element 106 and the correspondence signal of both the horizontal position indicator symbol generator 99 and the vertical position indicator symbol generator 100, the decoder 87 is controlled via the logical AND gate 105 in such a way that it directly receives the output of the Umlauis memory 89 via the multiplex device 85 fed back so that the shifted characters are now stored in the buffer memory 86. In addition, the bistable elements 106, 108 are reset to the zero position x, possibly with a slight delay. At the end of the space, the multiplexing device 85 is switched to line 90 for a character period so that the additional digit is filled with a "space character". Then the remaining characters are stored in the buffer memory 86 in the correct place.

The idea of the invention can also be used in other ways. So can in a single Control cycle several characters inserted or deleted

will. With the same device it is possible to add more Perform operations such as: replacing a character with a space; This means that ilor circular storage 89 the normal cycle after like before executes, but that the multiplex device 85 during the relevant symbol period the inter-cm'-communication line 90 connects to the buffer tank. Furthermore, in a known manner, the Output of the buffer memory 86 can be connected to inputs of a plurality of circular memories, each of which is used for this purpose can be connected to a television monitor with its output. In the example described above the clock pulse series was changed to the circular memory. In a corresponding way, the clock pulse rate to the buffer memory can be influenced in such a way that d; eat the information a relative shift in certain cases it is not necessary to that the buffer memory 86 has a capacity that is large enough to contain the information of all lines of characters / u: it is then necessary that the capacity of the buffer storage and the circular storage overall is sufficient.

For this purpose 2 sheets of drawings

25th

30th

35

40

45

50 '

60

65

Claims (2)

Patent claims: 1. Arrangement for the reproduction of at least three separated by space lines Lines of characters on a picture tube which has a circular buffer memory with a capacity for contains all these characters and a circular memory for a line of characters, the content of which is synchronous with the illustration of a line of characters circulating on the screen and during the illustration at least a gap line on the picture tube is transferred from the circular buffer memory, wherein a clock pulse generator circulating the information in the circulating memories and a Control device a relative displacement of the mapping of part of a line of characters controls the picture tube, thereby marked e i c h η? '. that an output of the circular memory (89) via a multiplexer (85), which also has an information input (90, 91) for new data to be entered Having character information is connected to an input of the circular buffer memory (86) and that a correspondence signal of an X-V cursor symbol generator (99,100) controls the multiplexer (85) so that the input of the circular buffer memory (86) selectively one under control of a changed pulse train of the clock pulse generator (94) shifted by at least one character position with respect to the information in the circular buffer memory (86) Part of the line received from the circulating memory (89), with one being re-imaged with the EWifugti- Character of the multiplexer (85) by the correspondence signal during gen uso many character transmission units, are available as new characters to be mapped to the information input (90,91) is switchable. 2. Arrangement according to claim 1, characterized in that that the circulating buffer memory (86) is constructed as a shift register.