DE2144935C3 - Color display device - Google Patents

Description

60

The invention relates to a color luminance cigcgcräl, Jas works in the line grid process, for display / on Information from a data processing facility (Processor), with several renewal memories for storing items that can be fed in by the processor Character-symbol codes and color codes to determine the color of at least one of characters and symbols, with a character-symbol generator to implement the character / symbol codes in the conversion memories into video signals, with a color decoder for decoding the color code from each renewal memory in color signals and with a control device for controlling the Renewal memory, the character-symbol generalor and the color decoder, so that a color visual display device the video signals and the color signals from the color decoder correspond to the video signals indicates.

In common color display devices in which a unit cell of a memory is closely connected with a unit display area on a screen results in a change in color in the center of successive signs, symbols or picture elements to create a gap that looks like this as large as a unit area at the point of such a change, although the usual one Display of a table is in no way affected by the gap. On the contrary, such a one Is a gap that is equal in size to a character even beneficial and is often formed on purpose. In certain areas of application, therefore, a such a conventional color display device quite satisfactorily serves its purpose.

However, when information requiring processing in an electronic computer is both complicated as well as being extensive in quantity. a visual display device must also have colored graphs or curves on / own to enable the communication between the surgeons and the electronic computer to simplify and improve. Fig. 1 shows part of a display panel of a substation, in which the three states of excitation, shutdown and failure of a circuit breaker, transformer. Resistance etc. are shown in red. Green and white, respectively, while the intermediate lines are shown in yellow are held.

It is readily apparent that this display panel in a state of high information density as shown in FIG. 1, not by a conventional display device can be held, which creates single-character gaps and in which the display is very coarse.

One way to overcome these difficulties is to do so. Color codes and characters To store symbol codes separately, which are shown in a suitable temporal link. This is known (GB-PS 1 045 929). in the case of a color display device, a renewal memory for storage of entered character-symbol codes and of color codes / for determining the color at least one of the signs and symbols to be provided, the sign. Symbol codes and color codes independently can be saved from each other. Furthermore, a sign is a symbol generator in this color display device provided which converts the character-symbol codes in the renewal memory into video signals. A Color decoder dccodicrt the color codes from the renewal memory in color signal. Finally, in this known carbs luster, one is used Control device for its temporal application of the video signals and the Farbbsignalcn from Color decoder according to the video signals. As for the number of taxation memories, so

a color display device is also known (US-PS 3? 93 614) which uses multiple refresh memories *.

These known devices allow one simultaneous display of two or more characters. Symbols or figurative elements or any gap between them (Space) on a unit area in a single color, but with them two or no more signs, symbols or picture elements in two or more colors on a healing surface are displayed.

It is therefore an object of the invention to provide a color display device of the type mentioned at the beginning to indicate the two or more characters, symbols or picture elements Can display in two or more colors on a unit area.

This object is achieved according to the invention in that one formed from logic elements VoiTang circuit within the control circuits downstream of the renewal memories Color display device is provided, which causes that either the color video signals derived from the memory output signals of the one priority is given to the renewal memory or the color video signals of a predetermined color while the other color video signals appearing at the same time are suppressed, respectively.

The color display device according to the invention can two or more characters, symbols or figurative elements on a unit area in two or more colors Show.

It is advantageous that output lines of a pointer display control circuit be connected to special input terminals the priority circuit are connected and that the logic elements of the priority circuit are designed so that the respective pointer color compared to the color of the same time from the Renewal storage symbols to be displayed takes precedence.

It is also advantageous that output lines of a pointer display control circuit are connected to specific input terminals the priority circuit are connected and that the logic elements of the priority circuit are designed so that the output of the pointer display control circuit opposite the color signal of the characters / symbols from the renewal memories is given priority and the color of characters / symbols to be displayed by the output of the pointer display control circuit in this way it is determined that a color is assigned to each renewal memory.

A pointer means a light line to designate a display position or display likelihood the display screen, e.g. B. a cathode ray tube.

The invention is explained in more detail with reference to the drawing. It shows

Fig. 1 is a network diagram that is represented by the inventive Color display device is displayed,

F i g. 2 the circuit diagram of an exemplary embodiment of the invention,

F i g. 3 an exemplary embodiment purely in the renewal storage from F i g. 2 stored information,

F i g. 4 the circuit diagram of a further embodiment of the invention,

F i g. 5 shows a signal diagram to explain the Embodiment of FIG. 4,

F i g. 6 shows the circuit diagram of a further example the invention,

F i g. 7 is the circuit diagram of part of the circuit of FIG. 6 on a smaller scale,

F i g. 8 is a diagram showing the problems with color display;

SF i g. 9 is a diagram showing an example of how color mixing by an embodiment ^; el is avoided according to the invention,

F i g. 10 is a circuit diagram of another embodiment of the invention for avoiding mixing ίο of colors, this Ausfül.rungsbeispiel a modification of the circuit of F i g. 7 is

11 shows the circuit diagram of a further exemplary embodiment of the invention for preventing color mixing,

• 5 F i g. 12 shows the circuit diagram of the priority circuit from FIG. 11,

13 shows an embodiment of the invention with pointer display,

14 shows details of FIG. 13, 15 shows another embodiment of the invention in connection with pointer display and

16 details of the exemplary embodiment according to F i g. 15th

An embodiment of the invention is shown in FIG. 2 pictured. There, 1 denotes a data processing system or processor, and 2 denotes a display device and at 3 a visual display device.

The processor i produces an output of H) bits, each 7 bits of a character symbol (including of picture elements forming an image) and 3 bits of a color signal. The tax arrangement 2, upon receipt of the output signal from processor 1, decodes the data to convert data into a to display the predetermined position in the display device. The control arrangement 2 has buffer registers 20 and 20 '. which shows the timing of the data transfer from processor 1 to renewal memories 21 and 21 'in Adjust depending on the states of the renewal memories 21 and 21 '.

The renewal memories 21 and 21 'in this exemplary embodiment, which store 7-bit character signals and 3-bit color code signals, are used to renew the display data and have dynamic shift registers formed from MOS transistors. A character 'symbol generator 22 only decodes character and symbol codes selectively among the codes of e.g. B. 10 bits and converts these into video signals for scanning the display device 3. A color code decoder 23 identifies color codes which are divided into the three primary letters by a color code encoder 24 which in turn generates red (R), green (GV and blue (β) signals. D flip-flops 25R, 25G and 25β the red. green and blue signal. aND gates 26R, 26G and 26B generate color signals and video signals corresponding to the associated color. A deflection control circuit 27 controls the position of the Datenan / EIGE. A Zeitsleuerschaltung 28 coordinates the zeiilichen the end of the data transfer from the renewal memories 21 and 21 'or the processor 1 the timing of the generation of the video signals from the character / symbol generator 22 and the timing of the operation of the deflection sounder 27 for displaying the desired data in a desired 65th position reversed in its Bctriel for each field by a Zeitstcucr circuit 28 to decide from which of the two sets of update memories information

should be read out. In the renewal memories 21 and 2 \ 'are provided a memory 21 α for character / symbol codes of the renewal memory 21, a memory 21b for color codes thereof, a memory 21'α for character / symbol codes of the other renewal memory 21' and a Memory 21'h for color codes thereof. AND gates 29a, 29'a, 29 /) and 29 '/) are used to control the transfer of information stored in each memory by means of the binary counter 28'.

The operation of the exemplary embodiment from FIG. 2 will be explained. Data are processed in processor 1. Characters, symbols and colors which are processed in the processor 1 are coded and fed via the buffer registers 20 and 20 'into the renewal memories 21 and 2Γ, so that they are stored in parallel in these memories. From the encoded data, the character and symbol codes are encoded by the character / symbol generator 22 for conversion into a sequence of video signals. On the other hand, color codes are read by the color code decoder 23. The color signals thus read are divided into the three primary colors by the color code encoder 24 which generates output signals R, G and B corresponding to each color, whereby the D flip-flops 25R, 25G and 25β are set. Output signals from these flip-flops, which are combined with the output signals from the character symbol generator, are fed to the AND gates 26R, 26G and 26ß so that a video signal of a desired color appears on the display device 3.

The characters symbol code memory 21 α and 21 'α of the renewal memory 21 and 21' are now to be considered in more detail. In the memories 21a and 21b α stored information is read out alternately at each field. That is, the timing control circuit, a reversal of the binary counter 28 'will cause 28 at every other field so that the AND gates 29 a and 29 h opened for a certain period and the AND Glieder29a and opened 29b for the remaining period to the read out information stored in the renewal memories.

It is now assumed that the output signal of the binary counter 28 'is fed into the AND gates 29a and 29 /). Character / symbol codes are read from the memory 21a in the renewal memory 21 and color codes from the memory 29b at predetermined intervals via the timing control circuit 28. The character / symbol codes, together with the output signal from the binary counter 28 ′, are fed into the AND element 29a, the output signal of which is fed to the character / symbol generator 22. On the other hand, the color codes are fed together with the output signal from the binary counter 28 'to the AND gate 29b , the output signal of which is fed to the color code decoder 23. The character / symbol codes. which are fed to the character symbol generator 22 are converted into video signals. Of the color codes supplied to the color code decoder 23, one of a predetermined color is read and divided into the three primary colors by the color encoder 24 connected to the flip-flops 25R, 25G and 258. The information stored in the flip-flops 25 R. 25 G and 25 B is fed together with the video signals from the character, symbol generator 22 to the AND gates 26 R. 26G and 26B, while the output signals are fed into the display device 3. Information is presented in color on a
predetermined position on the sickle cigec device 3
represented by the deflecting noise 27, the
is controlled by the timing control circuit 28. in the
Renewal memory 21 'stored information
is read out for display in much the same way. There is one between the information signals in the memory 21 α and those in the memory 21'a
such a relationship that the former are in the form of color signals are displayed which are stored in the memory 21 b, and the latter in the form of color signals which are stored in the memory 21 '/), where
the transfer between the two is made every '/ eo ^s
will. As a result, for that becomes unaided
provided a beholder's eye the information
displayed on the screen of the display device 3 as if the information in the memory 21 a
and the information in memory 2Γα at the same time
would appear.

In order to understand the exemplary embodiments of the
Facilitating invention is an example of in the
Renewal memories 21 and 21 'of FIG. 2 stored information in FIG. 3 specified.

From the drawing it can be seen that the area
(/.A) in Fig. 1 of the memory address of the block /
and corresponds to No. A, hereinafter referred to as (/. A) M
quoted. When scanning a field, (./ '. K) M to
(/ '. k + \ 2) M. which have been read from 21a at
(/.A) to (/.A- + 12) on the display device 3 in
the color (white in this case what a glitch
means) displayed, which is determined by 21 b . At the
Scanning the next field is now after displaying 7 "+ 1 to j + m in sequence
(/, A) 'M to (jk + 12)' M from 21a ' read and at
(/, k) to (/ '. A + 12) are displayed in the display device 3.
The latter display is superimposed on the previous one and its color is made independent by 21 '/)
determined by 21 /). For example, at (7. A + 4) and
(/. A + 7) in FIG. 1 the white "" of the previous field is crossed with the red "Jj" symbol
displayed, while at (/, k + 11) the white »«
is displayed superimposed on the yellow character »x«.
If the field scanning is repeated every '/ ,, "s,
gets the character / symbol information from a
Memory displayed every V ₃₀ s.

In addition to the procedure described above, at
which the character symbol generator is used
under chronological division of his operation for
every field, it is obvious that you can also do so much
Can use character / symbol generators, like
There are renewal stores

There is another method of using the
Sign / symbol generator by time division. A
Embodiment of this method is now on
Hand of fig. 4 and 5. In Fig. 4th
can be seen renewal registers 21 and 21 '. Locking or locking registers 220 and 220 ' for setting the change in the output signal of 220 and
a switching gate 230 for feeding in the characters
Symbol codes from the two renewal memories
in a suitable time sequence, a color switch gate
for generating an output signal in the form
the color codes from the renewal stores to the
correct time, pattern lock register 241
to 243. which temporarily receive the dot pattern of the characters read out and symbol codes for

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to Erk wii En on u η Ze clv au sir Ze wi < 22 we nö to Im lh «ge · un tri Ze S \ Sy

bc un füi 28 ra (D mi W in es Ai G 24 wi ve

ce Z <ni el

d d 2 I u a \\ d w d

store a certain period: multiplexer 251 and 252 for converting the dot patterns read out in parallel into serial video signals and OR gates 261, 262 and 263. The other assemblies have the same reference numerals as FIG. 2.

The operation of this exemplary embodiment is now illustrated with the aid of a time-signal diagram in FIG. 5 explained. Information processed in the processor 1 is, as in the embodiment of FIG. 2 in the Renewal memories 21 and 21 'are stored in such an ordered manner as shown by FIG. 5a and 5 b is indicated. Assume that the character symbol code (D 1-Λ) of the renewal memory 21 and the data code (Dl-B) one above the other on the same unit display area of the cathode ray tube are displayed, and that also the characters symbol codes (Dl-A) and (Dl-B). similar as in Fig. 5c and 5d. into the interlock registers 220 and 220 'can be read simultaneously with the color codes. It is also assumed that it takes 500 ns to operate the character / symbol generator 22 and that it takes 1 us to generate the given Information on a unit display area of the cathode ray screen to display. It is also assumed that it takes 500 ns to switch gate 230 to switch. (The time required to operate the switching gate 230. must not be 500 ns or the Exceeding the time necessary to operate the sign symbol generator.) The sign Symbol code (Dl-A) is used in the character symbol generator 22 during the first 500 ns and the Code (D 1-B) read in during the second 500 ns by actuating the gate 230, as in FIG. 5 g and 5 h is indicated. All timing for these steps is done by the timing circuit 28 made. The signal read into character / symbol generator 22 during the first 500 ns (Dl-A) is converted into the video signal (Pl-A) and latched with the output latch register 241. During the next 500ns the signal DI-B fed into the character's symbol generator 22, where it is converted to the video signal PI-B and latched to the output latch register 243. Simultaneously is in the output lock register

241 stored information or the signal Pl-A locked to output lock register 242 in turn. This is done to maintain temporarily the signal Pl-A in the lock register

242 from output latch register 241 as the result of the character, symbol code D2-A. the in the Character / symbol generator 22 for display on the next unit display area of the renewal memory 21 has been fed in. the display of which continues for 1 μβ. That is, the ones in the output lock register Stored information is locked as shown in Figures 5i through 5k. the Video signals PI-A and PI-B. those with 242 or 243 are locked are converted into multiple serial signals by the multiplexers 251 and 252 and converted into the AND gates 26R. 26G and 26B as well as 26R. 26G 'and 26ß' fed in. The output signals of this AND gates are fed to OR gates 261, 262, and 263 to run on the cathode ray tube to be displayed. The control of the color signals is done in the same way as on hand of the embodiment of FIG. 2, the only difference being that that they are controlled by the temporal relation hung to the character / symbol code. In this embodiment one color is through identifies the color code decoder 23 by timing the switching of the character / symbol code and fed to the color code encoder 24. It is possible with this setup. Information in display multiple colors on a unit display area. This method also allows display with less flicker than in the exemplary embodiment

ίο from F i g. 2.

A further exemplary embodiment will now be described with reference to FIG. 6 to 9 explained.

F i g. Fig. 6 shows a color display device 3 having two sets of renewal memories each containing information can display in two colors on its unit display area. A color code control sound 10 is used to distinguish between a color code and a data code. A memory control circuit 200 distributes color codes and data codes from the color code control circuit 10 to the Storage.

There are also renewal memories 21 and 21. Sign symbol generators 22 and 22 ', color flip-flops 70 and 80. Color control gates 90 and 100, a timing control circuit 28, a deflection control circuit 27. a color drive circuit 13 and a color cathode ray tube 3.

The operation of this embodiment will now be described with reference to FIG. 6 explained. Information supplied by an electronic computer or other external device is obtained as a sequence of words (which are normally 8 bits). This information has control data for the allocation of a renewal memory door memory purposes. Color codes for assigning a display color and data codes for specifying characters and symbols to be displayed. This composite information is fed into the color code memory circuit 10, from which the color codes and data codes are sent out separately. The output signal of the color code control circuit 10 is fed into the memory control circuit 200 for controlling a renewal memory for storing the relevant signal. The output signal of the memory drive circuit 200 is supplied to the renewal memories 21 and 21 'and stored there. The color and data codes stored in the renewal memories are read out synchronously with the movement of the electron beams of the color cathode ray tube. The color codes are fed into the color control gates 90 and 100 after clocking by the color flip-flops 70 and 80, respectively. In contrast to this, the data codes are fed into the character generators 22 and 22 'and, after being converted into characters, are fed to the color control gates 90 and 100, symbol signals (video signals). The color control gate 90. which the output signals Rl. GI and ßl of the color flip-flops 70 and the symbol signal V 1 received. works as an AND element, while the color control gate 100 receives the output signals R2, G2 and BI of the color flip-flops 80 and the symbol signal 12 to work as an AND element, with output signals RiV, GlK BlK R2K G21 and BlV for controlling a Electron guns are generated. The output signals from the color Meuergattern 90 and Ϊ00 are fed into the color control circuit 13, which acts as an OR gate and its output signal in the color cathode ray

509640/17

tube 3 feeds, with an electron gun is driven by a deflection signal sent from the deflection control sound 27 for display on the cathode ray tube screen is produced. The color control gates 90 and 100 and the color control circuit 13 of FIG. 6 are shown in more detail in FIG. 7 pictured.

7 shows AND gates 91, 93, 101, 103, and also OR gates 131, 133. As has already been explained, the color codes Rl. Gl, ßl, R2, G2 and ß2 and the character / symbol signals Vl and Vl are fed into the AND gates 91 to 93 and 101 103, and as a result, the output signals are in the form of the signals RlV. Gl V. BlV, RlV, GlV and BlV generated. These signals are fed into the OR gates 131 133 of the dye control circuit 13, which generates an output signal which is then fed to the color calhode ray tube 3.

This embodiment according to FIG. 6 and 7, however, have a disadvantage that has yet to be mentioned. An example of information provided by the color display device of FIG. 6 is displayed is shown in FIG. 8 pictured. F i g. 8a shows a sample power flow diagram. Information contained in unit display areas or areas (k, j + 1). (k + 1. '+ 5) and (A- + 2, j + 4) are indicated in FIG. 8 a. 8 b and 8 c shown enlarged. In the case of the display of FIG. 8 b, the color of the character H is mixed with the background color, while in the display of F i g. H c and 8 d the difference in the two colors causes these to be mixed with one another at their crossing points.

A logic circuit is explained with reference to FIG. 10, a display taking place without the color mixing just mentioned. FIG. 10 shows a modified circuit from FIG. 7. In FIG. 10, FIGS. 6 and 7 similar parts have been given similar reference numerals. A priority circuit 15 enables information to be clearly displayed in multiple colors (two in this embodiment) in a single unit display area. The priority circuit of the exemplary embodiment has an inverter or NOT element 150 and AND elements 151 to 153. As in FIG. 6, information stored in the renewal memories 21 and 21 'is fed into the color flip-flops 70 and 80 and the character-symbol generators 22 and 22', respectively. The output signals Rl. Gl and ßl of the color flip-flops 70 and the output signal V 1 of the symbol generator 22 are fed into the AND gates 91, 92 and 93 of the color control gate 90. The output signals Rl, Gl and B2 of the color flip-flops 80 and the output signal V1 of the character / symbol generator 22 'are fed into the AND gates 101, 102 and 103 of the color control gate 100. The output signal Vl of the character symbol generator 22 is also fed into the priority circuit 15 in order to give a priority or a priority to the color signals Rl, Gl and Bl and the character signal Vl . The output signals

RFl = Ri F. Gl F. ßl F + R2F G2F B2F GFl
BFl = Rl
= / Π F.
F. Gl
Gl F.
T Bl
Bl F +
F + R2F
R2F G2F
gTf B2I
B2F YVi
MVi = Rl
- Rl V
V Cii Ci F.
F. ßl
ßl F +
V 4 R2F
R2F G2F B2F
B2F

the AND gates 91, 92 and 93 of the color control gate 90 are fed to the OR gates 131, 132 and 133 of the color control circuit 13. On the other hand, the output signals of the AND gates 101, 102 and 103 of the color control gate 100 are fed into the AND gates 151, 152 and 153 of the priority circuit 15. The signal Vl is the priority-transmission 15 supplied through the NOT gate 150 to the AND gates 151,152 and 153rd The output signals of the circuit of Fig. 10 can be expressed by the following logical equations:

RV = Rl · Vl + Rl FT · Vl (1) GV = Gl ■ Vl 4 Gl ■ Vl ■ Vl (2) BV = Bl ■ Vl + Bl- Vl ■ Vl (3)

These output signals are obtained at the OR gates 131, 132 and 133 of the color control circuit 13. The output signals from the OR gate are fed in the form of video signals RK GF and BV of the color cathode ray tube 3 for display by the latter. This embodiment is so constructed that the video (character / symbol »signal Vl of a memory given a priority or a precedence is converted by the NOT gate 150 to be a logical product of its combination with a color video signal of the 8b, 8c and 8d, similar to information of Figs. 9a, 9b and 9c, are displayed independently.

In this exemplary embodiment, the priority circuit is set between the color control gate and the color control circuit. A modification is possible according to which the video signal Π can be used to decide on the priority, in order to prevent the feeding of the video signal V 2 into the color control gate 100, or the signal V 1 can be used as one of the three input signals of the AND gate of the Color control gate f00 can be used to suppress color mixing. Another embodiment which avoids color mixing is shown in FIG. 11 pictured. This embodiment is structured in such a way that color signals are given priority according to their types. In other words, the priority is determined according to the color of the information displayed. In this figure, assemblies similar to those in FIG. 6. 7 and 10 provided. There is a decoder 16 which, after converting the video signals RlK GlK and BlF and the video signals R2F, G2F and B 2 F. generated by the color control gates 90 and 100 into a single color, operates as an OR gate and outputs signals in the form of color videosianals RFl. GFI. BFl. Wl, MFl, CFl and WVl are generated in a manner determined by the following logical equations:

zeu stir Wc R. log gai we

away; sch Fi am

RI um ste gec

the dei gai vic Bl Su GI Dc 17 in Fa Ia ₅ de sti F; M flat

isl St rn Λ er D

cv \ wv \

RW ■ GW ■ BW + RlV ■ GlV ■ BlV RW-GW- BW + RlV ■ GlV ■ BlV

(9)
(10)

A priority circuit 17 generates an output signal in the order of predetermined priority or priority. If z. For example, if priority is given in the order of R. M, Y. W, C, B and G , the logical equations according to which the output signals are generated by the priority circuit 17 are as follows:

RVl = RVl MKl
YVl (H) MVl =
YVl = RVl ■
WvI WVl (12)
(13) WVl = YVl CVl (14) CVl = WVl ■ BVl (15) BVl = CVl ■ GVl (16) GVl = BVl ■ (17)

This priority circuit is shown in more detail in FIG. 12th shown, from which it can be seen that the priority circuit consists of AND gates that are in the Fig. 12 are shown in detail connected to one another.

An encoder 18 combines the seven video signals RF2 to GV1 into the three color video signals RV, GV and BV which drive the color cathode ray tube CRT3 . This is expressed by the following equation:

RV = RVl + MVl + YVl + WVl (18)
GV = GVl + YVl + CVl + WVl (19)
BV = BVl + MVl + CVl \ WVl (20)

The color signals Rl, Eq. Bl, RX Gl and Bl and the video signals V 1 and V 2 are supplied to the color control gates 90 and 100 from the memories. The output signals of the gates 90 and 100 in the form of color video signals RlK GlK BlK B2K GlV and BlV are fed into the decoder 16. These signals are converted into the seven color video signals RV1. GVl, GKl. YVl, MVl, CVl and WVl converted by the decoder 16 in order to be fed into the priority sound 17, which brings the input signals into the predetermined order of priority. The seven color video signals which have left the priority circuit 17 are converted back into RK G V and BV by the decoder 18 and fed to the color cathode ray tube. In this way, the color cathode ray tube 3 displays information without any mixture of two colors on a unit display area.

An exemplary embodiment in connection with a pointer control will now be explained. In Fig. 13 is an input / output control circuit 1000 for controlling information input from external devices (such as an electronic computer) and available for output to external facilities. A first renewal memory 21 consists of a first data memory and a first color memory. A second renewal memory 21 'consists of a second data memory and a second color memory. A character / symbol generator 22 receives character / symbol codcs from the first renewal memory 21 and generates video signals as an output signal. A color control circuit 13 generates upon receipt of the output signal from the character / symbol generator

ίο 22 and the first color code from the color control circuit 790 color video signals. This creates a link between color codes and video signals. A character-symbol generator 22 'receives the second file code and generates character / symbol signals,

₅ while a color control circuit 800 generates color video signals upon receipt of the output from the character symbol generator 22 'and the second color code. A timing circuit 28 sends a timing signal to each circuit. A deflection control circuit 27 is also provided, and a pointer display control circuit 4. The color drive circuit 13 receives output signals from the color control circuits 790 and 800 and the pointer display control circuit 4 and combines them into a color video signal for driving an electron gun. Finally, a color cathode ray tube 3 can be seen.

The actual connection of the components of the pointer display control circuit 4 to the components

J _{0 of} the color control circuit 13 can be seen in FIGS. 14a and 14b.

The embodiment of Fig. 13 serves to to control a suitable refresh memory if information related to the pointer color is changed, is suppressed or added. Let it be B. assumed that when information is displayed on on the screen of the color cathode ray tube 3, the pointer is green in color. if this information is about the data of the first renewal register 21 is displayed while the pointer color is blue. if the Information about the data of the second renewal memory 21 'is displayed. If there is no data in the Are saved, the pointer color ζ. Β Chosen red to indicate it is possible. to write in some renewal store.

The operation of this embodiment will now be explained with reference to Figs. Information is distributed to the data memory and the color memory of the renewal memories 21 and 21 for storage and converted into video signals via the symbol generator 22 and 22 '. The information stored in the color memory and the output of the character symbol generators 22 and 22 'are fed to the color control circuits 800 and 790, respectively. which in turn color video signals Rl 1. GIl, BVl. RI 2. GVl and BVl output to the color control circuit 13.

The pointer display control circuit 4 also supplies three kinds of signals to the color drive circuit 13.

Let us now detail this pointer display control circuit with reference to FIG. 14a explained. It can be seen there flip-flops 41 and 42 and AND gates 43 47. In the AND gates 43 and 44 fed a Zeicbenzustimmungssignal CRSROK from the timing-transmission 28 (shown in Fig. 13) and the Ausgancssignale V 1 and Vl of the mark Symbol generators 22 and 22 '. The Auseanexsienale of the AND gates 43 and

21

935 f

44 are placed in flip-flops 41 and 42. That is, the appearance of any video signal in the display position determined by the pointer causes a flip-flop to be set in accordance with the data memory involved. This flip-flop is reset by the pointer transfer signal CRSRSHFT which is generated by the timing control circuit 28. The signal generated by timing circuit 28 to indicate a scanning line for pointer display (the tenth scanning line RST10 in this embodiment) is fed to AND gates 45-47 together with the output signals from flip-flops 41 and 42. The AND gate 45 receives the signals CRSROK and RST 10 and the I output signal from the dsm flip-flop 41 and generates the pointer control signal CRSR 1 when data occurs in the update memory 21. The AND gate 46, in contrast, receives the signals CRSROK and RST 10 and the I output of the flip-flop 42 and generates the pointer control signal CRSR2 in the presence of data in the refresh memory 21 '. The AND gate 47, which receives the signals CRSROK and RST 10 and the 0 output signals from the flip-flops 42 and 43, generates the pointer control signal CRSRO in the absence of data in any of the refresh memories.

The pointer control signals are output from the pointer display control circuit 4 shown in FIG. ] 3 generated. The color drive circuit 13 receives the pointer control signals CRSRi, CRSR2 and CRSRO. die> arbvideosignalei? Kl, GVi, BVh RVl. GVl and BVl and the output signals from the character symbol generator and feeds final signals RV, GV and BV into the color cathode ray tube 3 for controlling an electron gun. The color control circuit 13 is shown in more detail in FIG. 14b.

In Fig. 14b can be seen OR gates 131 135. Furthermore AND gates 136 141, the blocking inputs indicated by a small circle. Links 131, 132, 136, 137, 138. 139, 140 and 141 produce output signals

(CRSRi + CRSRl), (Fl + CRSRi + CRSRl), RVl [CRSRl + CRSRl),

GVi (CRSRl + CRSRl). BVl (CRSRl + CRSRl). (Vl + CRSRl + CRSRl) -RV2, GVl (Vl + CRSRl + CRSRl) and BVl- (Vi + CRSRl + CRSRl).

The output signals of the OR gates, i.e. the final signals RV, GV and BV, are determined by the following logical equations:

RV = CRSRO + (CRSRl + CRSRl) ■ (RVl + Vl ■ RVl) GV = CRSRl + (CRSRl + CRSRl) ■ (GVl + Vi ■ GVl) BV = CRSRl + (CRSRl + CRSR2) ■ (BVl + Vi · BVl )

(21) (22) (23)

RVL, GVL or BVL are multiplied by Vl, 'in order to prevent color mixing at the crossovers of data codes in the memory 21 and 21st Further, the color video signals representing the display information are multiplied by (CRSRl + CRSRl) in order to avoid color mixing in the portion where the pointer and the information overlap each other. The output signals RV, GV, BV , etc. of the color drive circuit 13, which satisfy equations (21), (22) and (23), are fed to the color cathode ray tube so that the beam from each electron gun is deflected by a deflection signal from the deflection control circuit 27 will.

As a result, information is displayed on the screen of the color cathode ray tube 3 while the pointer is timed to move by the pointer shift signal CRSRSHFT , showing a particular color to indicate which refresh memory stores information for each display area.

Another embodiment will now be explained in connection with the pointer control. According to the previous exemplary embodiment, it is easy to determine which memory is information developed when one of the stores is involved in the display in the display area. When data codes of Both memories participate in the display in a unit area, the pointer consists of one Mixture of colors, e.g. B. Green and Blue. This indicates an indication in relation to both memories, however, confused when the information stored in one of the memories changes. This in

Fig. 15 shown embodiment is this Avoid disadvantage. According to this exemplary embodiment, the character and the symbol are in the Positions that are determined by the pointer are displayed in colors corresponding to the memories involved, to make it clear which memory is allocated to the character and symbol. In Fig. 15 are Similar assemblies are provided with similar reference symbols as in FIG. 13. In Fig. 15 are present a pointer control sound 4 'and a color control circuit 13'. The pointer control circuit 4 'and the Color control circuit 13 'are shown in more detail in Fig. 16a and 16b.

The operation of this embodiment will be explained with reference to FIG. As stated earlier, the color video signals RV1. GVl. BVl. RV2, GVl and BVl fed from the color control circuits 790 and 800 into the color control circuit 13 '. The output signal of the pointer control circuit 4 'is also fed into the color control circuit 13'.

The pointer control circuit 4 'will now be described with reference to FIG. 16a. In this figure, flip-flops 401 and 402 and AND gates 403 409 are provided. The Zeichenzustimmsignal CRSROK from the timing control circuit 28 in Fig. 15 as well as the output signals Vl and Vl of the character / symbol generators 22 and 22 'are fed to the AND gates 403 and 404. The outputs of AND gates 403 and 404 are set into flip-flops 401 and 402, respectively, which are reset by the pointer shift signal CRSRSHFT generated by the row control circuit 28. The exit

signal the A 'AND-du.s Vi in which the Ai AND-generates; signal Das A CRSRi das da Videos, ort voi tiangss Link * das Si,

create

The CRSR is supposed to be an I pointer. I through RV, G gemäl: signali 13 've control beami the A

15th

IS 10 * 2 and RSRO r new-

signal ig. 13 gt the ISRO, GV2 chen · oden-I ⁷ ZUr i. The ;. 14b

songs iperr-

signal V 1 of the character / symbol generator 22 and the output signal of the flip-flop 401 are fed to the AND gate 405 , which generates the video signal M 1 V as an output signal, which represents the data code in the pointer position. The ORSROK signal and the output signal from the flip-flop 401 are fed to the AND gate 406 , which generates a signal MEM 1 which indicates that a video signal from the refresh memory 21 is present in the pointing position. The output from flip-flop 402 and the CRSROK signal are fed to AND gate 407 which generates the MEM 2 signal which indicates that a video signal from refresh memory IY is present at the pointer location. The signals C2 and Ml V and the output signal of the flip-flop 402 are fed into the AND gate 408 with a blocking input, which receives the signal MI V , the AND gate

the video signal Ml V generated as the output signal by the renewal memory 21 'in accordance with the pointer position. The signal and the output signal RST CRSROK 10 from the timing control circuit 28 are supplied to the AND gate 409 which generates the pointer control signal CRSR. This signal is supplied from the pointer control circuit of FIG. 15 to the color drive circuit 13 '.

The color control circuit 13 'will now be explained with reference to FIG. 16b. There are OR elements 1301 1305 and AND elements 130fr 1311 with blocking inputs, which are indicated by a small circle. The OR gates 1301 and 1302 generate output signals (CRSR + MEMi) and ICRSR + Vl + MEMI), while the AND gates 1306, 1307, 1308, 1309, 1310 and 131J output signals

RVl ICRSR + MEMl), GVl (CRSR + MEMl), BVX (CRSR + MEMl), RV2 (rRSR + Vl + AiEiW 2), GV2- (CRSR + Vl + MEM2) or BV 2- (CRSR + Vl + MEMl)

produce. The output signals of the OR gates 1303-1305 or the final signals RV, GV and BV are expressed by the following equations:

RV = CRSR + (CRSR + MEMl) ■ RVl + (CRSR + Vl + MEM2) ■ RVl (23)

GV = MlV + (CRSR + MEMl) ■ GVl + (CRSR + Vl + MEM2) ■ GV2 (24)

BV = M2V + (CRSR + MEMl) ■ BVl + (CRSR + Vl + MEMl) ■ BVl (25)

• owns.

The reason why a color video signal should be blocked by CRSR is to avoid color mixing due to overlapping of the pointer and the display information. In this case the pointer is always indicated in red by the signal RV. The output signals RV, GV and BV 'are identical to the output signals RV, GV and BV the Farbansteuerschaltung 13 according to Fig. 16b' of FIG from the Farbansteuerschaltung 13. 15. The outputs of the Farbansteuerschaltung 13 'are fed to the color cathode ray tube 3, so that Deflection signals c from the deflection control circuit 27 cause the electron beam from each electron gun to be deflected, whereby information is displayed on the screen of the color cathode ray tube 3 in a color indicating the data memory in which this information is stored.

From the foregoing description it can be seen that the color of the pointer or the character in the position determined by the pointer is differentiated according to the memory involved, so that It is very much easier to use a renewal memory for changing, canceling or adding to display information in a display position on the screen through a keyboard or the like.

15 sheets of drawings

1 to share Vl, utterance utterance

Claims (3)

Patent claims: 1. Color display device that works in line grid works to display information from a data processing device (processor), with several renewal memories for storing those that can be fed by the processor Character / symbol codes and color codes to determine the color of at least one of the Characters and symbols, with a character / symbol generator to convert the character / symbol codes in the refresh memories into video signals, with a color decoder for decoding the color code from each renewal memory into color signals and with a controller to control the renewal memory, the character / symbol generator and the color decoder, so that a color display means the video signals and the color signals from indicates the color decoder corresponding to the video signals, characterized in that that a priority circuit formed from logic elements (13. 15 or 17 | within the control circuits of the color display device connected downstream of the control memories (21, 21) (3) is provided which causes either of the memory output signals derived color video signals of one of the renewal memories (21 or 21) or the Color video signals of a predetermined color are given priority while simultaneously occurring other color video signals are suppressed. 2. Color display device according to claim I, characterized in that output lines one Pointer display control circuit (4) to special input connections of the priority circuit (Fig. 14 b) are connected, and that the logic elements the priority circuit (Fig. 14b) are designed such that the respective pointer color compared to the color of the one to be displayed at the same time from the renewal memories (21,21 ( Signs symbols takes precedence. 3. Color display device according to claim 1, characterized in that output lines one Pointer display control circuit (4 ') to special input terminals of the priority circuit (F i g. 16 b) are connected, and that the logic elements the priority circuit (Fig. 16b) are designed such that the output signal the pointer display control circuit (4 ') to the color signal of the characters symbols from the Change memory (21. 21 ') takes precedence and the color of the characters to be displayed symbols by the output of the pointer display control circuit is so determined. that each renewal memory is assigned a color.