DE2104266A1 - Attachment device with a cathode ray tube - Google Patents

Description

Display device comprising a cathode ray tube

The invention relates to a device for displaying information in the form of letters, numbers or similar characters that are stored, for example, in a memory of an electronic computer or are stored, and in particular a display device having a device using a dot matrix Cathode ray tube.

Although various display devices have been proposed, none of these devices has been proposed Proven to be completely satisfactory.

In a known device, for example, a A special cathode ray tube known as a beam shape tube is used, in which an embossed Letters or similar characters provided character electrode is arranged in front of an electron gun and a potential at a deflection electrode arranged in front of this electrode on the side facing the cathode

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POlT HEADQUARTERS: β MUnchtn 90, Eduard-Schmld-Str. 2

is created to a desired letter or a select similar character and cause part of the character electrode to let the electrons through, while the remaining parts of the electrode block the electrons. Those not blocked by the drawing electrode Electrons place the selected character in the desired part of the fluorescent screen of the cathode ray tube ': Ujr. These However, the device has the disadvantage that the spread of the Electron beam poor resolution of the cells Pattern. Are also with this device. the selection of characters and the deflection voltage are not exact determined, then in addition to the selected characters, other characters are often displayed on the screen. There In addition, the character is selected according to an analog variable, the operation of the display device is unstable; furthermore, since the number of characters that can be formed on the character electrode is limited, it is not possible to represent a larger number of characters, for example letters or the like.

Another known device is known as a point system in which a single electron beam is controlled so as to successively scan a drawing electrode in the longitudinal or transverse direction; when the electron beam reaches the desired point on the drawing electrode, the intensity of the beam is increased so that the point concerned lights up on the screen. Den, Sections _A the not

Suppression of

are to light up, a signal for / brightness is impressed, which is used to select the character memory, which comprises a group of circuits for displaying the selected character in dotted form on the screen. At this known device which uses scanning lines to represent multiple letters or similar characters must however, the sampling time can be shortened significantly, thereby the whole device becomes extremely complicated.

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In addition, since the signal duration of the individual signals applied to the various components is short, the characters cannot can be displayed in a stable manner.

Another known display device called Segment Synthesis sy st em is similar to the point system described above, but the sections between the dots are not suppressed, but reproduced as a segment of a continuously bright line to represent the characters.

In this device, vertical, horizontal and inclined segments are provided in a memory and there are those of read out a certain reference point kept separate code of the segments. The read codes are then over A digital-to-analog converter is applied to a deflection coil to display letters and similar characters. The way of working this device is unstable because the periods of the vertical and horizontal deflection signals are short. Farther the stability of the device is impaired by its aging, since the read codes are in analog values for display to be converted from characters.

Another known display device uses a Lissajous' Sches picture diagram or pattern, in which signals of continuous functions both on the vertical and on the horizontal., arranged deflection coils are applied to represent characters with such patterns. In particular, the phase relationship between the time function of the function signals and the higher harmonic components obtained by Fourier transform of the time function are calculated in such a way that only those required to represent the characters Sections are made to light up. Although the characters displayed with this device are sharply demarcated and are clear, a function wave generator must be provided for each character, so that this device too

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becomes more complicated »The mode of operation of the device is again unstable because the symbols are also caused by analog quantities being represented.

In another known display device there is a special cathode ray tube with seven electron beams application «The through the electron beams on the screen seven dots shown are represented by bright dots formed by a matrix electrode arrangement provided in the cathode ray tube are selected, and points not shown are formed. As these seven points by deflection coils one after the other are diverted, the patterns of characters by the dots are under the control of one of an external character memory delivered signal reproduced. In this device, however, no character can be formed when the Rays are not deflected.

The object of the invention is to avoid practically all problems of the known devices and a to create novel display cathode ray tube, in which from a plurality of letters, numbers and the like Characters or patterns formed therefrom selected characters are displayed on the screen of the cathode ray tube can without the electron beam having to be deflected.

Furthermore, the display device should be of various types Be able to display characters clearly and stably,

In addition, the display device according to the invention without using a digital-to-analog converter sign different types can be represented with the help of a simplified circuit construction.

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In addition, the display device according to the invention in be able to display a large number of letters, digits or similar characters, be compact in structure and are suitable for use with electronic desktop computers.

In the case of a display device with a cathode, a matrix electrode arrangement, a screen, these tasks become and a cathode ray tube having a deflection coil arranged between the matrix electrode arrangement and the screen solved according to the invention by several separate ones with the matrix electrode arrangement connected memories dedicated to different groups of patterns to be displayed on the screen of Letters, digits and similar characters are provided, an address memory for storing the positions the screen on which the selected pattern of the characters are to be displayed, an information memory for Storage of the information for the pattern to be displayed, one on the output signals from the address memory and from the Information memory appealing device for the selective control of the various memories for the items to be displayed Pattern groups and a device for supplying deflection signals synchronized with the output signals of various memories to the deflection coil. ■

In the following a preferred embodiment of the invention is explained in more detail with reference to the drawings. Show it:

1 shows a block diagram of the basic structure of an embodiment the display device according to the invention,

2a and 2b are signal diagrams for explaining the mode of operation of the individual switching blocks according to FIG. 1,

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Pig. 3> 4 and 5 circuit diagrams to illustrate FIG

exemplary storage for letters, numbers or "katakanas" (Japanese characters) according to Fig. 1,

6 shows an electrical circuit of a gate circuit

according to Fig. 1,

Figures 7a, 7b and 7c on the CRT screen

symbols shown as well as the relationship between the position of the pattern and the addresses of secondary storage,

8 shows a table of values to illustrate the state

the address characters stored in a register,

Fig. 9 is a diagram showing the structure of a cathode ray tube according to FIG. 1 used dot matrix electrode arrangement and

Fig. 10 is a view on an enlarged scale

of a character displayed on the screen of the cathode ray tube.

1 shows a block diagram of an embodiment of a display device with the cathode ray tube according to the invention. In this arrangement, the output signal of a memory 1 is coupled to an auxiliary memory 2, the output of which is connected to a register 3. The majority of the outputs of the register 3 is connected to a decoder 4 which, in turn, Dj ations via ^L - D _n to a gate circuit 5 is connected. The remaining outputs of register 3 are connected directly to gate 5 via lines z ^ * £ 2 and gj.

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A part of the outputs of the gate 5 is via lines A ^ - A _n with a letter memory 6, another part is via lines H ^ - N _n with a digit memory 7 and the remaining part of the outputs is via lines K ^ - K _n connected to a katakana memory 8. The outputs of these memories 6, 7 and 8 are applied to a dot matrix electrode array 19b of a cathode ray tube 18.

A clock pulse generator 15 is connected to a counter 12; a part of the outputs of the counter 12 is connected to the memories 6, M 7 and 8, while another part is connected to an address register 10 and the remaining part is connected to a synthesizer 15 for the X-axes which delivers step-shaped signals. The signal emitted by the address register 10 is fed to a read control circuit 11, the output of which goes to the secondary memory 2. A part of the outputs of the synthesizer 15 is connected to a deflection coil 17 of the cathode ray tube 18, while another part of the outputs is applied to a synthesizer 16 for the Y-axes which generates step-shaped signals, the output signal of which is also connected to the deflection coil 17, see above that the synthesizer 16 also forms a deflection circuit of the cathode ray tube. r ^

At the inputs of a start or stop control circuit 9 are from an external signal source, for example one not shown electronic computer generated start and stop signals applied. The signals of the control circuit 9 are the synthesizers 15 and 16, the address register 10 and the counter 12 are fed.

To explain the mode of operation of various components according to FIG. 1, FIGS. 2a illustrate uri ^^^^^^ oil: abscissas represent time and ordinates represent voltage or current. The points t%, t-2 »15 etc. indicate different points in time,

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at which the shape of at least two signals changes. In Fig. 2a, 22 is the waveform of the output voltage of the clock pulse generator, and 2j5. to 28 the output signals of the counter 12 and 29 the output signal of the X-axis synthesizer 15 *, ie the signal of the current flowing through the deflection coil 17 is shown. According to FIG. 2b, the signal; 50 has the same form as the signal 29 in FIG. Axis synthesizer 16 or the waveform of the current applied to the deflection coil I7 is shown. Notably, the courses of the signals j50 and J51 are not limited to the examples shown, but the number of steps of these square waves changes depending on the number of rows of letters or similar characters to be displayed on the screen of the cathode ray tube 18. The points Tq, T ^ etc. on the time axis t- according to FIG. 2b indicate the times at which one or both courses of the signals ~ $ 0 and J51 change.

3 * 4 and 5 illustrate typical circuit diagrams of the memories 6, 7 and 8 according to FIG. 1, where Y ^ to Υξ represent the lines which transmit the signals 24 to 25 according to FIG. 2a. The lines X ^ - X ^, which are each provided with the same indices in FIGS. 5 to 5 as in FIGS. 1 and 2, are connected to the dot matrix: electrode arrangement 19b of the cathode ray tube 18. In FIGS. 1 to 6, lines corresponding to one another are provided with the same letters and indices.

According to Fig. 3, one end of each resistor> -, 53 # 5 ¹ I, 35 and J) G to a line y ^, y ₂ , yj, y ^ and y ^ and the other end in each case to a line 47, 48, 49, 50 or 51 connected. The line 47 is connected to the anodes of

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Diodes 75-77, whereas their cathodes are connected to lines 68, 69, 70, 71 and 72, respectively. A line 48 is connected to the anode of diodes 79 and 89, the cathodes of which are connected to lines 67 and 70, respectively. Line 49 is connected to the anodes of diodes 78 and 87, the cathodes of which are connected to lines 66 and 70, respectively. Likewise, the line 50 is connected via diodes 80 and 86 to the lines 67 and 70 and the line 51 via the diodes 81, 82, 85, 84 and 85 to the lines 68, 69, 70, 71 and 72, respectively. The other ends of these M lines 66-72 are connected via the diodes 59 to 65 connected to the lines Xj to Χγ. Furthermore, the lines 66 - 72 are connected to the anodes of the diodes 52 - 58, the cathodes of which are jointly connected to the output line A .. of the gate circuit 5. Such a combination of diodes means that information is stored in the form of the letter "A". The components assigned to the other lines A2 to A _n are also connected in the same way. The combination of diodes assigned to line A ₂ thus stores the information in the form of a letter ¹¹ B "and the corresponding combination of line Aj stores the information" C ".

Similarly, as shown in FIG. 4, combinations of diodes which store information in the form of the digits 1, 2, 5, etc. are assigned to the output lines Nj-N _{n of} the gate circuit 5.

According to FIG. 5, combinations of diodes which store information in the form of Katakana characters corresponding to “a ^{! T} ,“ e ”,“ u ”etc. are also assigned to the output lines K ^ - K of the gate 5.

FIG. 6 illustrates a typical circuit diagram of the gate circuit 5 according to FIG. 1, the output lines Aj-A _{n being connected} to the anodes of diodes 89-95. Although the number of diodes corresponds to the number of lines Aj - A _u,

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Fewer diodes are shown for the sake of simplicity. The cathodes of these diodes 89-95 are connected together to a line I3I, which is referred to below as the G ^ line. The lines A ^ - A _n are also connected to the anodes of the diodes 96-102, the cathodes of which are connected to the lines I35-141, which are hereinafter referred to as lines G,. - G _{n are} designated.

Other output lines Nj - N are similarly connected, that is, these lines are connected through diodes I03 through a designated in the following as line Gg line I32 - 109 and connected via diodes 100 to 116 to the lines G ^ - G _n connected.

The output lines Kj-K _{n of} the gate circuit 5 are also connected in a similar way, namely via diodes _{117-123 to a line designated below with g-, and are also connected via diodes 124-130 to the lines G 1} -G _n .

The FIGS. "Ja, Jh and ¹ Jo illustrate illustrated character patterns and their positions on the screen of the cathode ray tube 18 as well as the link between these positions and the addresses in the secondary memory. FIG. 7a illustrates the representation of letters, numbers and similar characters on the screen of the cathode ray tube, Fig. 7b the position of the pattern of the letters, digits and the like to be displayed on the screen of the cathode ray tube 18 and Fig. 7c finally the link between the address symbol numbers ^B 11 ~ ^B mn of ^the secondary memory 2 and the symbol numbers S ^ - S _{mB |} according to FIG. 7b.

8 is a table of values showing the state of the address symbol numbers B ^ - BJ _n when they are stored in the register 3. In this table, D ^ - D _n indicate logical values of the content of the register 3 which appear after decoding by the decoder 4 on the relevant output lines Dj - D _n , while gj, g ₂ and g- ^ the logical fourth

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which appear on the relevant output lines g .., g ₂ and g, of register 5 according to FIG. 3 *

9 illustrates the typical structure of the dot matrix electrode arrangements 19a and 19b of the cathode ray tube 18, which are arranged in front of the electron gun of the cathode ray tube o According to this figure, the electrode plates y ¹ * - y ^f c and x ^f ^ - χ ¹ γ with the leads y ^ - yp- or x .. - x ~ connected. The electrode plates thus form a 5 x 7 matrix. Each electrode plate y ^ - y, - is equally spaced with five ^

distributed openings provided and each electrode plate x ¹ ^ ™ - x ^f "many seven equally spaced openings. The openings of the electrode plates y ¹ -j - y ¹ 5 and those of the electrode ^{plates x f} * - χ ¹ γ lie at the intersection points of the electrode plates and are aligned one above the other. A shielding plate 142 is inserted between groups of electrode plates or behind the electrode plates χ ¹ λ - χ ^{1 y.} If a positive potential of, for example, 15-20 V is now applied to the electrode plates in question, this positive potential attracts the electrons emitted by the cathode 20 and allows them to pass through the openings. The electrons passing through the openings are accelerated and hit the screen in order to display 35 points on it. M catfish some of the positive electrode plates instead of a negative mass-P; tential to be the the grounded electrode plates located in the openings corresponding points on the screen not shown or not made to light up. While the electrode plates y ¹ * - y ¹ 5 are scanned one after the other with a positive pulse, the desired pattern can be generated, provided that some of the electrode plates x- - Xy of the other group required to represent the symbol are synchronously applied with a positive pulse of a letter, a number or a similar character are represented by the dots.

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Fig. 10 shows an example of a pattern displayed on the screen of the cathode ray tube, in which a letter ^11B "is displayed.

The mode of operation of the display device according to the invention is explained in more detail below.

When a start pulse signal is applied to the start or stop control circuit 9, a start signal is fed into the relevant circuitry. The control circuit 9 causes the phases of the deflection signal, the information read signal and the scanning pulse of the matrix electrode arrangement to coincide. The signal supplied by the control circuit 9 actuates the address register 10 and the counter 12, which have been held in their "set" state, in order to transfer the information from the memory 1 to be displayed. At this point in time, taking into account the position of the letter to be displayed on the screen, the memory content is determined so that the position of the position numbers S «... - SJ _{n of} the screen of the cathode ray tube according to FIG. 7b and the position of the address numbers A ^ λ - AJ _{n of} the secondary memory (Fig. 7c) are brought into agreement with one another. Some of the outputs of the counter 12 are switched to the address rogister, so that counter output signals are applied to it as a function of the output signal of the clock pulse generator 13. If the content of the address register is changed by activating the read control circuit 11, the content of the secondary memory 2 is consequently written into the register J> one after the other and in accordance with the order of the patterns or characters to be displayed on the screen of the cathode ray tube 18. Because of this, it is essential that the register is written to without affecting the content of the secondary memory in any way. Three code signals of the I halts written in the register 3 are used as switching signals for selecting the memories 6, 7 or, while the remaining contents of the memory are off

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Codes for selecting the pattern of letters, digits or characters. These code signals are fed in via the detector of the gate circuit 5, whereby one of the letter or number symbols, the patterns of which are present in the memories 8, ¹ J and β, selected and the selected pattern corresponding to the memory in synchronization with a pulse signal of the

for.scanning
Counter 12 / is applied to the matrix electrode arrangement 19b, the selected character pattern being combined with the pulse signal to form the desired overall pattern. To display the pattern in the desired position on the W screen, the synthesizers 15 and 16, which form the deflection circuit, cause deflection currents synchronized with the pulse used to form the pattern to flow through the deflection coil of the cathode ray tube. After the end of a working cycle, the content of the register 3 reads a code corresponding to the pattern of the letter or character to be subsequently displayed from the secondary memory 2, mt & this code is impressed on the matrix electrode arrangement of the cathode ray tube in order to display the newly selected pattern on the screen. At this point, since the deflection currents provided by the synthesizers 15 and 16 have been varied in steps, the pattern of the next symbol can be displayed in the desired Jh position. These display processes are repeated with such a repetition frequency that they

appear to the viewer continuously and not flickering / and thus several letters or similar characters can be displayed on the screen at the same time.

The following is the mode of operation of the individual components and of the entire system according to the block diagram of FIG. 1 described in more detail. The store 1, the secondary store 2, the Address register 10 and read control circuit 11 are obviously not limited to those specifically shown Character types restricted. If the display device, for example, for an electronic desk calculator or the like. is used, the memory 1 can be omitted; in this case

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the secondary memory 2 is used as the memory of the computer. This means that the components must be arranged in such a way that so that the contents of the sub-memory 2 successively at high speed in accordance with the character arrangement on the Screen and by a single output pulse from the counter 12 can be read into register 3. This is at application conventional computer technology possible. For the sake of simplicity, it is assumed that the symbols to be represented are the Letters, numbers or the like. corresponding codes in turn be read when the counter 12 provides an output signal and stored in register 3.

The waveform of a clock pulse generated by generator 15 is characterized by curve 22 in FIG. 2a. The start or Stop control circuit 9 has a single RS flip-flop for storing start and stop signals. In the following it is now assumed that the address register 10, the counter 12, the X-axis synthesizer 15 and the Y-axis synthesizer 16 are set when a stop signal is received. If the start or stop control circuit 9 receives a start signal, then the address register 10, the counter 12 and the synthesizers 15 and 16 are triggered under predetermined conditions. The register 10 must display an address number B ^ (FIG. 7c), while the counter 12 must correspond to the values of _{the signals 23, 24, 25, 26, 27 and 28 at the time t o according to FIG. 2a.} In addition, the signals of the currents flowing via the synthesizers 15 and 16 to the deflection coil 17 of the cathode ray tube 18 must _{correspond to the signals 23-28 of the counter 12 at the time t Q} and the current signals 30, 31 at the time T ₀ in FIG. 2b. If these conditions are met, the content of the address number B ₁₁ is stored by the read control circuit 11 in the register 3, since the content of the set register 10 _{indicates the address number B 11} (FIG. 7c). Three codes of the content are applied to the gate circuit 5. Most of the recorded codes will, however

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the decoder 4 is fed, the output signals of the gate circuit 5 are impressed. For example, the contents of the address numbers B ^ - B ^ _{1 of} the sub memory 2 shown in Fig. Je are stored in the register 5. FIG. 8 illustrates the codes read from register J5 and fed directly into gate circuit 5, as well as the codes read from register J and fed into gate circuit 5 via decoder 4. If, for example, according to FIGS. 6 and 8, the address number of the secondary memory is B ^ - ■ and the code of the number 100 is represented by a positive logic voltage value and the gate circuit to the letter memory 6 is switched through, while the gate circuits to the Katakana character memory 8 and to the digit memory 7 are in the locked state, only the letter or the character of the memory 6 is selected. It is further assumed that a code "1" is indicated by a positive voltage and a code "θ" is indicated by a zero voltage; so a positive voltage is applied to the line g ^, while the lines £ >> and g ^ according to FIG. 6 are at a zero voltage. If the positive potential impressed on the line gj is higher than the voltages on the lines Aj-A _n , the diodes 89-95 connected to the line g ^ are reverse-biased so that they do not let any current through. The diodes 10j5-I09 connected to the line gp, on the other hand, are biased in the forward or forward direction and allow a current to flow. As a result, all lines Nw | - W _n at zero potential. Since the line g ·, is also at zero potential, the lines K ^ - K _{n also have} zero potential. Since all lines N .. - N _n and K ^ - K _n have zero potential, the diodes 96 - 102 connected in the forward direction shown in Figure 6, to prevent that the lines A .. -. A from the zero potential be applied. The letter memory is selected by this switching behavior. ifi

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The codes lying on the lines D ₁ .. D _n are impressed on the lines Ga to G _n. In the event that the codes _{lying on the lines Dj - D n} have positive logic voltage values, only the line G «. a positive voltage impressed on the diode 96 of the selected letter memory 6 is then generated by a negative bias voltage, since the voltages on the lines A ^ and G .. are the same or the voltage of the line G .. is higher than the voltage impressed on line A ^; the diode 96 is thus in its blocking state. However, since the lines G ₂ - G _{n are} at zero voltages, the diodes 97-102 are forward biased so that the lines Ag - A _{n are} at zero voltages.

A positive potential is thus only applied to the line A ^ in order to select it * In fact, however, the line Ag is _{not impressed with a positive potential during the time spans t Q} to t ^ and t ^ ₂ to t ..., (FIG. 2a) , but no disturbance occurs during these time intervals because no letter or similar character pattern is displayed on the screen of the cathode ray tube. This state can be explained in more detail with reference to the mode of operation of the circuits according to FIGS. As a result of the operation of the counter 12, voltages corresponding to the positive pulses 2h -28 according to FIG 18 is periodically sampled by these voltages. The pulse voltages applied to lines y ^ - y ^ are switched to the diode matrices for letters, numbers and the like and appear on lines x ^ -x ™. In this way, codes corresponding to the letter or number symbols appear on lines X ^ -X ₇

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in the order y ^ , y ₂ , y ,, y ^ and y ^. As mentioned, the lines xj-x ″ according to FIGS. The diodes 52 biased in the opposite direction or reverse direction do not conduct, since a positive potential is impressed on _{the selected line A 2.} The positive pulses 24-28 according to FIG. 2a correspond to the voltages occurring on the lines yj-y, -. In the time interval between t ^ and tg, a positive potential is applied to line y .., while lines y ₂ - V ₁ - are at zero voltage. This positive potential is applied to the lines xx- Xrr via the diodes 81-85 and thus also to the diodes _{61-65. Since the lines y 2} -y, - are at zero voltage, the lines x .. - and X _{2 also have zero voltage} Zero voltage. According to the same working principle, the positive potential is applied to the lines y ₂ - y, - one after the other, so that a series of pulses is formed on the lines χ, - x ^. In the illustrated embodiment, a code series is formed from the diode matrix connected to the line A .. and the voltage impressed on the lines y .. - yj by the point matrices 19a and 19b of the cathode ray tube 18 in order to represent a letter "A". As mentioned, the diodes 59-65 prevent interference from the diode memory blocks of other letters or characters.

When a selected letter has been displayed on the screen in this way, the operation for displaying the next letter or character is initiated. A by differentiating Enzleren at the time tg rising edge of a pulse 25 (Fig. 2a) of the output signal of the counter 12 of Figure 1 or the falling edge of a positive pulse of the / signals. 24 - 28, for example dee pulse 28 (Fig. 2a) received impulse causes a change of the

+) the lines y ^ - y, - impressed - 18 -

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State of the X-axis synthesizer 15, which supplies step signals, for the purpose of changing the magnitude of the current flowing through the X-axis deflection coil, represented by the signal 29 in FIG. 2a, at time tg. Simultaneously with this change in value of the deflection current at time tg, the pulse sequence shown in FIG. 2a reads. 23 the letter to be displayed later or the character from secondary memory 2 (FIG. 1) and stores it in register J5 * whereupon similar processes are repeated. If the selected letters at predetermined positions S ... - S .. (Fig. 7b) corresponding to the content of the address numbers A ^ - A ^ _n (Fig. 7c) of the secondary memory 2 are displayed on the screen of the cathode ray tube, the content of the relevant address numbers Bp .. (Fig. 7c) at the position S g .. are shown in Fig. 7b. This position is determined by the X-axis synthesizer 15 and the Y-axis synthesizer 16, which form the deflection circuit according to FIG. At this time, a signal from a counter provided in the X-axis synthesizer 15 is applied to the Y-axis synthesizer 16 to change the state of the square wave generated by the latter. The counter in the X-axis synthesizer 15 is a η-stage counter for the letters, digits and similar characters that are to be formed to the side of the positions ^ ³ H " ^S m1 S ^em ^ ^ß Fig. 7b. Immediately after the formation of a Such a symbol at position S ₁ (Fig. 7b) by the counter, a pulse signal is applied to the Y-axis synthesizer 16 to change its state as shown in Fig. 2b The waveform shown in Fig. 2b illustrates that via the synthesizer 15 through the deflection coil 17 of the cathode ray tube 18, this course being similar to the signal 29 according to Fig. 2a. Obviously, this signal illustrates the case for η = 6 (Fig. 7b), ie the case in which the number of letters to be displayed is equal to 6. Signal 3I in Figure 2b illustrates a signal generated by Y-axis synthesizer 16 under the control of an output signal from the counter provided in synthesizer 15. Signal JO illustrates that.

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perpendicular deflection current of the deflection coil of the cathode ray tube 18; if according to Flg. 2b the value of the signal at the times Tg, ¹ ^ Ao * ^ 18 ^ ³¹¹ ^ ^ 24 Meiert, the value of the signal 31 also changes.This example illustrates a case in which six letters or similar characters located next to one another are replaced by the im Synthesizer 15 provided counter on the screen of the tube 18 are displayed, synchronously with the signal 30 · During very short time intervals, ie at the times T, To, T ^ ••••• Toit it is necessary to use the synthesizer 15 and 16 supplied signals 30 and 31 to impress a suppression signal by the synthesizer 14 generating such signals and to apply it to the cathode 20 or to the grid 19 of the cathode ray tube 18. By repeating the aforementioned operations, all of the contents of the secondary memory 2 are displayed on the screen of the cathode ray tube 18. Since these processes are repeated continuously with a frequency of less than 1/30 s, at which the display takes place evenly and without flickering, until a stop signal is finally applied to the start or stop control circuit 9, all contents of the Sub-storage displayed in the standing state on the screen of the cathode ray tube 18.

Although a single letter is represented by 35 dots in the above-described operation, it is by increasing the number of points of the dot matrix used in the cathode ray tube, the letters or the like are possible To show characters more clearly. When it comes to characters that present themselves with a lower score let, the number of signals impressed on the dot matrix electrode arrangement can be reduced.

The patterns of the letters or characters to be displayed are dependent on the content of the register 23, which is via the lines g .., gp and g ^, applied directly to the gate circuit 5

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is selected, this content being applied to the gate circuit 5 via the decoder 4. If the number of letters or characters to be stored in these components increases, the number of lines Dj D _{n also increases} , as a result of which the circuit arrangement of the decoder 4 becomes complicated. In this case, the memories 6, 7 and 8 are formed by a plurality of divided circuit blocks; in addition, the number of the codes on the lines g ^, g ₂ and g ^ z for switching and disabling the gate code corresponding to the number of divided blocks of the letter, number and character memory is increased, which is similar by a diode circuit as in Fig. 6 can be formed. With this structure, the number of terminals Gj-G _{n can be} reduced, thereby simplifying the circuit structure of the decoder 4 determined by the content of the memory 1 of the electronic calculator.

When the contents of the memory 1 are expressed by simple binary values, as used to decipher the lines g-1 * g2 ^and S3. supplied code is required, an additional decoder must be switched on in these lines. Here, a decoder can be provided between the secondary memory 2 and the register 5.

As mentioned earlier, in the case of an electronic. Desktop computer the memory 1 can be omitted, while the secondary memory 2 is used as memory for the computer, so that a real ^ .time display device for the computer is created.

The invention thus provides an improved display device with a novel cathode ray tube, with the Help letters, numbers and similar characters can be displayed on the screen without the electron

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beam of the cathode ray tube must be deflected; the deflection of the electron beam takes place only to the corresponding one Separation of the digits displayed on the screen from each other. Letters and similar characters are indicated by selective actuation of the matrix formed, which acts as a kind of matrix switch. This is why the Display device very stable, so that the letters or characters displayed on the screen of the cathode ray tube are more stable can be displayed than is possible with conventional display devices. Since the period of the stepped or «Jfc The electromagnetic deflection coil of the cathode ray tube is long, a stable deflection current can be generated in a simple manner to ensure stable operation, so that im Compared to the known display devices, significantly more letters and similar characters can be displayed. The device for generating character patterns, the gate circuit 5, the letter memory 6, the digit memory 7 * the Katakana or character memory 8 and the counter 12 are through flip-flops or logic circuits with diode combinations formed so that the character pattern without the otherwise required digital-to-analog conversion on the screen ^ being represented. Advantageously, a stable display can be achieved with an inexpensive and simple device in which no special and complicated components have to be provided. Because the by the clock pulse generator 13 generated clock pulses to various components of the counter 12, the quality of the characters displayed on the screen of the cathode ray tube will also not improve Frequency fluctuations of the clock pulse impaired. Since the characters continue to be represented or formed by dots can become a large one by increasing the size of the memory

Number of such characters are represented.

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109885/1615

Although the invention is in a preferred embodiment shown and described are understood by those skilled in the art within the scope of the invention numerous changes and modifications are possible.

In summary, the invention provides a display device using a cathode ray tube with a dot matrix electrode arrangement, wherein the device has a plurality of memories connected to the matrix electrode arrangement for various types of Pattern, an address register for storing the positions on the screen on which selected Patterns are to be displayed, a memory for storing the information for the pattern to be displayed on the output signals from the address register and from the memory responsive device for the selective control of the various memories and a device for placing synchronized with the output signals of various memories Having deflection currents to the deflection coil of the cathode ray tube.

109885/1615

Claims (10)

Claims Display device with a cathode, eiie matrix electrode arrangement, a screen and a deflection coil arranged between the matrix electrode arrangement and the screen having cathode ray tube, characterized by several separate memories connected to the matrix electrode arrangement, which are for different groups of patterns of letters, numbers and similar characters to be displayed on the screen are provided, an address memory for storing the positions on the screen on which the selected patterns of the characters are to be displayed, an information memory for storing the information for the patterns to be displayed, one on the output signals from the address memory and the information -Memory responsive device for selective control of the various memories for the pattern groups _{9 to be presented} and a device for delivery of deflection signals synchronized with the output signals of different memories to the deflection coil. 2. Apparatus according to claim 1, characterized in that the content of the information memory under the Control of the address memory is read and stored in a register and that the outputs of the The register is connected to the various memories of the pattern groups via a decoder and a gate circuit are. 109885/1615 3. Device according to claim 2, characterized in that that several register outputs are applied directly to the gate circuit, while the rest of the time the register outputs are applied to the gate circuit via the decoder. 4. Apparatus according to claim 1, characterized in that each memory has a number of parallel-connected Diode matrices for the pattern groups, one matrix for each pattern. 5. Apparatus according to claim 1, characterized in that the means for supplying the deflection signal an X-axis synthesizer generating step signals and a step signal generating Y-axis synthesizer. 6. Apparatus according to claim 5 * characterized in that that one. Start or stop control to control the operation of the two synthesizers as well as the Operation of the address memory is provided. 7. Device according to claim 5 * characterized in that that a clock pulse generator and a counter responding to its output signal for synchronous Control of the operation of the address memory, the various memories for the pattern groups and the two synthesizers are provided. 109885/1615 8. Apparatus according to claim 1, characterized in that the information memory is a main memory and has a lifting store, 9 «Device according to claim 1, characterized in that that the cathode ray tube has a grid which supplies suppression signals from a Synthesizer is applied » 10. display device for displaying letters, Numbers, and similar signs, characterized by a cathode ray tube with a cathode, a control grid, a dot matrix electrode assembly, a screen, and one between the matrix electrode assembly and screen arranged deflection coil, main memory for storing a variety of information for the patterns to be displayed on the screen, a register, an address register for storing the Positions on the screen at which selected patterns are to be displayed, one between the Main memory and the register switched on secondary memory to read the information from the main memory and to save the read information in the register under the control of the address register, a gate circuit, a decoder, connections to the delivery of output signals of the register directly to the gate circuit and for the delivery of further output signals of the register via the decoder to the gate circuit, several separate memories for different types of patterns between the output of the gate and the dot matrix electrode array of the cathode ray tube are connected and each of which is a plurality in parallel Has geüolialtete diode matrices, one each Matrix for each pattern, a deflection circuit for the deflection coil, each delivering a step-shaped signal - 26 - 109885/1615 Synthesizer or generator for the X and Y axes, a suppression signal connected to the control grid of the cathode ray tube ran a synthesizer or generator, a clock pulse generator, a counter responding to the output pulses of the clock pulse generator for synchronous control of the operation of the address register and the various separate memories, the step-shaped signals generating X-axis and Y-axis synthesizer, the suppression signal generating generator, and a start or stop control for controlling the operation of the address register, ^e: 5i and y-axis synthesizer or Generators and the meter. 109885/1615