DE2328920A1 - LIQUID CRYSTAL DISPLAY DEVICE - Google Patents

Description

Liquid crystal display device The invention relates to a liquid crystal display device with liquid crystal cells, each two arranged in parallel at a distance from one another Have dielectric carriers which are each coated with conductive layers and between which a liquid crystal is enclosed, with at least one carrier with the conductive layer located thereon is optically transparent, and with a driver circuit for the liquid crystal cells.

Liquid crystal cells include electrodes made of metal oxide films exist, which are generally applied to two transparent faces, for example on glass plates. By applying an electrical voltage to the electrodes, icn Represent information such as numbers, letters, characters and the like by adding the voltage is applied to certain of the electrode segments.

The division of the electrodes into segments and the type of supply of the electrodes has been of the type of Trelber circuit. So far one has been used static driver circuit and a dynamic driver circuit.

In the case of a static driver circuit, one electrode is used as a collecting electrode applied to the voltage, while the other electrode is divided into a number of electrode groups is divided under, which each consists of a number of electrodes as they are used for Presentation of information is required, with the applied to these electrodes Voltage is controlled by information signals and column signals.

Dynamic driver circuits are time division circuits in which opposing electrodes each in a number of electrode groups are divided, where each group consists of a number of electrode segments, which are necessary to display the information, and which are connected to a group of electrodes applied electrical voltage is controlled by information signals while the voltage on the other electrode group is controlled by column signals.

5 it has been shown so far that the application of a dynamic driver circuit is difficult because liquid crystals have a considerable rise time and fall time have compared to other display devices, such as Nixi tubes, luminescent diodes etc..

The invention is based on the object of a liquid crystal display device of the type mentioned to create which a minimum of external connections has a long service life and in conjunction with a dynamic driver circuit has short switching times.

The solution to this problem is to be seen in the fact that the one conductive layer on the one support of each liquid crystal cell in a number of electrode segments is subdivided, the connecting tracks of which on an edge region of the associated carrier run that mutually corresponding electrode segments of all liquid crystal cells each at the edge area m eir, are connected to the other that the conductive layer on the other carrier of each liquid crystal cell forms a collecting electrode, and that the Driver circuit one output for each electrode segment group and one output for each collecting electrode.

The invention is shown below with reference to schematic drawings several exemplary embodiments in addition.

Figure 1 is a sectional view through a liquid crystal according to FIG the invention.

Figure 2 is a plan view of the liquid crystal of Figure 1.

Figure a. is a section along the line X-X of FIG.

FIG. B is a view corresponding to FIG. 3a with a modified version Embodiment.

Figure 4 is a top plan view of a liquid crystal with a reflective Electrode.

FIG. 5 shows graphs at the various outputs a driver circuit according to FIG. 6.

Figure 6 is a block diagram of a driver circuit according to the invention.

Figure 7 is a block diagram of part of the driver circuit according to Figure 6.

Figures 8a to 8f show graphs of the signals at various Setting the circuit according to Figure 7.

Figure 9 is a block diagram corresponding to Figure 7 of a modified one Embodiment of a driver circuit.

Figures 10a to 10f show curve representations of the signals at various Setting the circuit according to Figure 9.

The liquid crystal 100 shown in Figure 1 comprises a transparent one Electrode plate 10, which consists of a transparent carrier, such as a glass plate, on which a metal oxide film is applied as a transparent electrode 12. The metal oxide film, such as tin oxide or iridium oxide, is for example by vacuum evaporation on the Carrier applied.

The liquid crystal further includes a reflective electrode plate 13, which consists of a transparent carrier 14 and a reflective thereon Electrode 15 is made of a metal oxide, such as aluminum oxide. Between the electrode plates 10 and 13 is a liquid crystal 17, the through Isolating bar 16 is included. In order to allow the liquid crystal 17 to flow out avoid and around a predetermined distance between the electrode plates 10 and To maintain 13 are the insulating bars 16 with the surfaces of the electrodes 15 and 12 connected. The latter have connecting ends 18, 19 for connecting the liquid crystal to an external circuit.

FIG. 2 shows the transparent electrode plate 10 in a plan view the plane of the transparent electrode 12 for displaying a four-digit number. Each of the digits is through seven electrode segments 61, 62, 63, 64, 65, 66 and 67 formed.

The number 1 is represented e.g. by the electrode segments 62, 65, the number 2 through the electrode segments 51, 62, 54, 66 and 67, the number 3 through the electrode segments 61, 62, 64, 65 and 67, and the number 0 by the electrode segments 61, 62, 63, 65, 66 and 67. The electrode segment 68 is used to represent a Point.

A four-digit number is represented by the electrode segment groups 121, 122, 123 and 124 formed, each comprising electrode segments 61 to 68, formed by dividing the transparent electrode 12. From the vlektrode segments 61, 63, 68, 65, 67, 66, 62 and 64 of the electrode segment groups 121, 122, 123 and 124 are each connecting lines 131, 133 ... 138 to the edge area of the transparent Carrier 11 out and each with the outputs 31 to 38 of the driver circuit 30 connected, specifically via connecting lines 18. There are also conductor tracks 21, 22, 23, 24, 25 and 26 are provided, which are used to cover the electrode segments 61, 63, 68, 65, 57 and 66 of the electrode segment groups 121 to 124 serve one another.

The connection of the conductor tracks is carried out by means of a conductive binder 40, which, for example, a conductive coating agent with a content of Is palladium. A is used to avoid short circuits under the conductor tracks electrical insulator 50, such as silicon oxide.

For production, first the transparent electrode plate 11, for example a glass plate with electrode segment groups 121, 122, 123 and 124 made of tin oxide or iridium oxide produced in a manner known per se by vacuum evaporation, likewise the connection lines 131 to 137. The conductive binder 40 and the electrical Insulating agents 50 are then applied in the required amount and position and the Conductor tracks 21 to 26 connected therewith. In Figure 2 show the dash-dotted lines Lines 16 'indicate the position of the insulating bars 16 from FIG.

Figure 3a shows a section along the line X-X of Figure 2 and leaves in particular an electrode segment 67 and a conductor track 138 on the transparent Recognize carrier 11. The conductive binder 40 and the insulating agent 50 are each onto the electrode segment 67 or the conductor track 138 in a manner known per se applied, for example by a photo etching process. The conductor track 26 is by means of a conductive coating agent, which contains tin oxide or falladium oxide, applied, for example by vacuum evaporation or photo etching. This is how the electrode segment is 67 electrically connected to the conductor track 26 by the conductive binder 40, while the conductor track 138 is insulated from the conductor track 26 by the insulating means 50 will.

FIG. 3b shows a sectional view corresponding to FIG. 3a modified embodiment. As in FIG. 2, this is the electrode segment 67 and the surface area having the conductor track 138 on the transparent carrier 11 made and evenly coated with an insulating agent 15, such as one Epoxy resin, with the exception of the area where the conductive binder 40 is applied shall be. The conduction path 26 is then placed and sealed with conductive binders i40 is electrically connected to the parts below.

FIG. 4 shows a plan view of the reflective electrode 15 the reflective electrode plate 13 of Figure 1. On the transparent support 14 reflective electrodes 151, 152, 153, 154 are applied in the form of metal films, made of aluminum, for example. The connecting lines 19 are used to connect the outputs 1D, 2D, 3D and 4D of driver circuit 76 with electrodes 151, 152, 153 and 154, respectively. These electrodes are made of a transparent conductive material, such as Tin oxide, and then the arrangement is filled with a liquid crystal. The interrupted Lines 16 ′ in FIG. 4 again show the position of the insulating bars 16.

Assume that four digits are to be represented, e.g. the number 1234. The transparent electrode plate 10 and the reflective electrode plate 13 are arranged so that the electrode segment groups 121, 122, 123 and 124 den reflective electrodes 151, 152, 153 and 154 through the liquid crystal 17 im Distance of the insulating bars 16 opposite, and the columns of the electrode segments 121 to 124 form the first, second, third and fourth columns, respectively.

Figure 5 shows graphs for displaying various digits. When displaying in the first column, a signal is only sent to output 1D of the Driver circuit 76 and at the same time from a register 71 the number 4 in the converter 73 is fed.

The signal corresponding to number 4 is sent via outputs 32> 34, 37 and 38 and via the driver circuit 30 to the electrode 15 and to the electrode groups 121, 122, 123, and 124, which displays the number 4 in the first column.

Because the liquid crystal is excited when one reaches the threshold voltage excess signal voltage is applied to the electrodes of the same, can use a signal voltage such that the voltage between the ends only becomes higher than the threshold voltage when signals are applied at both ends, while the potential difference is smaller than the threshold voltage when signals are only applied at one end.

A signal is only sent to the display in the second column to the output 2D of the driver circuit 76 and at the same time the number 3 is derived from the Register 71 given to converter 73. The signal corresponding to number 3 arrives via the outputs 31, 34, 35> 37, 37 and 38 and through the driver circuit 30th to the electrode 152 or the electrode groups 121, 122, 123 and 124.

Similarly, the digits 2 in the third column and the number 1 in the fourth column is reproduced cyclically one after the other.

When a threshold voltage is applied to both ends of the liquid crystal, so that a current flows in a predetermined direction through the liquid crystal, a chemical change occurs in it, so that the service life is limited is. It is therefore better that the threshold voltage be applied to the liquid crystal to control so that the flow of current through the same is periodically reversed that so an alternating voltage is used as the driver voltage.

Figure 6 shows a preferred embodiment of a liquid crystal display device according to the invention for displaying four columns of digits. The one in Figure 6 as well The driver circuit shown includes a clock generator 70 which the register 71 feeds as well as a decimal counter 74 and a pulse generator 75. The register 71 has a ring line 72. The converter 73 receives signals from the register 71 and the decimal counter 74 and transmits a processed signal to the driver circuit 30. The liquid crystal 100 has electrode segment groups 121 to 124, the are each divided into eight electrode segments, with the same segments in these Electrode groups each connected to one another and each with one of the outputs 31 to 38 of the driver circuit 30 are connected. The reflective electrodes 151 to 154 are each associated with one of the outputs 1D to 4D of the driver circuit 76 connected, which is controlled by the pulse generator 75. If any information should be displayed in the first column, becomes the corresponding The signal content is transferred from the register 71 to the converter 73 and the output of the Pulse generator 75 is controlled by the clock 70 so that only the Output 1D of driver circuit 76 carries a signal. Be the same way processes the contents for the second, third and fourth columns for display.

At certain points of the outputs 31 to 38 of the driver circuit 30, signals are then generated which are sent to the electrode segment groups 121 to 124 are conducted and there only one of the reflective electrodes 151 to 74 one control voltage is carried, one display is only nier, while the others Columns remain dark.

Figure 7 shows the design of the driver circuits 30 and 76 in detail. Each of the logic circuits 80 includes two J'JD gates 81 and 82, each with two Inputs and an OR gate 83, whose inputs with the outputs of the two AND gates are connected, and finally an amplifier 84 for amplifying the Output signal of the OR gate 83 for generating a drive voltage E'V for the Liquid crystal 100.

The numbers 101 to 114 denote inverters. Further are the resistors R and capacitors C included in the driver circuit 30, the resistors R each have a logic circuit 80 having an output terminal 31 to 38 of the liquid crystal 100 and the capacitors C each to one of these output terminals lead and interconnected with their other connections and to the output of the Inverters 101 are connected. The outputs 13, 2D, 3D and 4D of the driver circuit 76 are each controlled by the input signals 1D '2D', 3D 'and 3D', which from the pulse generator 75 5tarmen. Similarly, the signals 31 'to control 38 ', although coming from the converter 73, the outputs 31 to 38 of the driver circuit 30. A high frequency pulse HF is applied to the input of the inverter 101, the also reaches one of the inputs of the AND gate 82 of the driver circuit 76.

Furthermore, the logic circuits 80 are still activated by low frequency pulses LF driven, namely the one inputs of the AND gate 81 of the driver circuit 76 interconnected and connected to the output of the inverter 102, which the low frequency pulse signal LF inverted.

The other inputs of AND gates 81 and 82 are from the control signals 1D ', 2D, 3D' and 4D 'controlled, namely the inputs of the AND gate 81 directly and that of AND gates 82 via inverters 103, 104, 105 and 106, respectively.

The inputs of AND gates 81 and 82 of logic circuits 80 of the driver circuit 30 are connected in the following way: one of the inputs of the AND gates 81 are interconnected and connected to the output of inverter 102. One of the inputs of the AND gates 82 are connected together and to the input switched on for the low frequency pulse LF. The other inputs of the AND gates 81 and 82 are connected to the inputs for the D signals 31 'to 38', namely the inputs of AND gates 81 through inverters 107 to 140 and those of the other AND gates 82 direct.

The operation of the liquid crystal display device according to the figures 6 and 7 is explained with reference to FIGS. 8a to f.

Assume that the four-digit number 1234 is displayed target. In Figures 8a and 8b it is shown that the low frequency pulse LF of the reaction time of the liquid crystal and the number of columns to be displayed depends.

The high-frequency pulse HF has a higher frequency than the cut-off frequency of the liquid crystal. The signals 1D 'to 4Dt for the driver circuit 76 are in an uninterrupted cycle according to the columns to be displayed generated. Therefore, outputs 1D through 4D of logic circuits 80 perform the low frequency pulses LF and the high frequency pulses HF are controlled, signals with waveforms which are combined from a pulse with a potential difference E 'and a high frequency pulse with an amplitude E ', as in Figure 8a is shown. The signals 31 'to 38' for the driver circuit 30 are each in such a compilation that the number 4 in the first Column, the number 3 in the second column, the number 2 in the third column and the number 1 will appear in the fourth column. The outputs of the logical Circuits 80 controlled by the low frequency pulse LF are via influences the resistors R and capacitors C, which have a substantial size, and each output comprises a pulse having a potential difference E 'and one High-frequency pulse with the amplitude E, which are superimposed according to FIG. 8b. figure 8c shows waveforms showing the potential differences between the electrodes of the Liquid crystal and the first column indicate if the number 1234 is in the liquid crystal 100 according to FIG. 7 is displayed, that is to say the potential differences at the electrode segments 61 to Ss of Figure 6 and the reflective electrode 151 of Figure 4 with the Electrode 151 as a reference electrode. The numbers 1 to 8 in brackets in Figure 8c denote potentials of the electrodes 61, 63, 68, 65, 67, 66, 62 and 64 with respect to the electrode 151, and it can be seen that five states are possible, namely the states D, E, F with a certain polarity and the states D ' and F 'with opposite polarity to the states of D and F.

Figures 8d, 8e and 8f serve to explain the states D, E and F of FIG. 18. FIG. 8d shows that a radio frequency pulse HF with an amplitude E is superimposed on a DC voltage component X corresponding to a signal (E ' - E / 2) with respect to the reference potential P. If this signal is greater than the Threshold voltage of the liquid crystal, it is excited and lights up. Since the threshold voltage of a liquid crystal when operated with direct current generally between 6 and 8 volts, the voltages E 'and E are chosen so that the signal voltage (E '- E / 2) can be higher than 8 volts.

FIG. 8e shows that the high-frequency pulse HF with the amplitude E around the reference potential P. Usually this is the cut-off frequency of the liquid crystal higher than 2 KHz. When the frequency of the high frequency pulse HF to an even higher If the value is set, the crystal does not light up.

Figure 8f shows a high-frequency pulse of amplitude (E '+ E) (with the frequency of the high-frequency pulse HF), which is around a zero line corresponding to the Reference potential P + E '/ 2 oscillates.

If the value EY2 is kept smaller than the threshold voltage of the Liquid crystal in AC operation, the liquid crystal does not light up.

Figure 8c shows that states D and F 'are of opposite polarity have like the assigned states D and F, where the direct voltage component Y of state D is equal to (E '- E / 2). In other words, the DC component X indicates that the current is flowing from electrodes 63, 65, 62 and 64 to electrode 151 flows while the DC component Y shows that current is from the electrodes 63r 65, 62 and 64 flows to electrode 151.

So if the number 12314 in the liquid crystal display device is displayed according to Figure 7, the number 4 appears only in the first Split. In the same way, the digits 3, 2 and 1 appear in the second, third or fourth column.

According to FIG. 7, an RC element is at the output of each logic circuit 80 with the resistor R and the capacitor C provided. Such RC elements can however instead also at the outputs of one of the driver circuits 30 and 76, which have fewer inputs and outputs having the driver circuit 76 from the lower frequency pulse LF, the output LF of the inverter 101 and the output HF is controlled while the driver circuit 30 is controlled by the output LF of the inverter 102. This will increase the number the required components reduced.

FIG. 9 shows another embodiment of the driver circuits 30 76, which is modified from the circuit according to FIG. 7, with the same components are provided with the same reference number. There are logic circuits 80 'and 80 " provided, which each comprise AND gates 81 and 82 with two inputs each, and an OR gate 83 with two inputs, each with the outputs of the AND gates and either an amplifier 85 for amplifying the output voltage of the OR gate to the voltage required to operate the liquid crystal 2 ED or an amplifier 86 for generating the drive voltage 2 ES for the same. The signals 1D 'to 4D', which control the outputs 1D to 4D, come from the pulse generator 75 (see Figure 6) to the driver circuit 76. In a similar manner, the control signals 31 'to 38', which control the outputs 31 to 38 of the driver circuit 30, of the Converter 73 passed to driver circuit 30. The inputs of the ID gates 81 and 82 of the logic circuits 80 'of the driver circuit 76 are in the following Way connected.

One of the inputs of the AND gates 81 are connected together and on connected to the output of inverter 102, which inverts the low frequency pulses. The one inputs of the AND gates 82 are also connected together and to the Input for the high-frequency HF pulses connected. The other entrances to the AND gates 81 and 82 are connected to the clamps for the signals 1D, 2D ', 3D' and 4D ' connected, namely the inputs of the AND gate 81 directly and those the AND gate 82 via inverters 103, 104, 105 and 106, respectively.

The outputs 1D to 4D of the logic circuits 80 'are connected to the Liquid crystal 100 connected. The inputs of AND gates 81 and 82 of the logical Circuits 80 'in driver circuit 30 are connected in the following manner: One of the inputs of the AND gate 81 are connected together and connected to the output of the inverter 102, while one of the inputs of the AND gate 82 is connected together and are connected to the terminal for the low frequency pulses LF. The others The inputs of the AND gate 81 are connected to the signal inputs 31 ', 32' .... 38 ', and the other inputs of AND gates 82 to the outputs of inverters 107 bis 114, the inputs of which are connected to the signal inputs 31t to 38 '. The amplifiers 86 amplify the output voltage to that required for the operation of the liquid crystals required voltage value 2E. The outputs 31 to 38 of the logic circuits 80 are connected to the liquid crystal 100.

The following is the operation of this liquid crystal display device for the representation of the number 1234, with the individual waveforms are explained with reference to FIG.

Since the signals lD 'to 4D', which are applied to the low-frequency pulse terminal, the high frequency pulse terminal and the driver circuit 76 arrive, and the signals 31 'to 38', which reach the driver circuit 30, the signals in FIG. 8a correspond, they are not included in Figure 10a.

The outputs 1D to 4D of the logic circuits 80 ', which through the high frequency pulses HF controlled by the low frequency pulses LF combined to impulses with a potential difference 2ED. The outputs 31 to 38 the logic circuits 80 "controlled by the low frequency pulses LF, are combined to form waveforms of the potential difference 2ES, as also from FIG. 10a emerges.

FIG. 10b shows the waveforms of the potential differences across the electrodes the first column of the liquid crystal QO for the display of the number 1234, where the Electrodes 151 are taken as reference electrodes to which the potential differences of the electrode segments 61 to 68 in the electrode segment group 121 of FIG. 2 (or Figure 6) and the reflective electrodes 151 in Figure 4 (or Figure 6) are related.

In FIG. 10b, the numbers in brackets denote 1 to 8, respectively the potentials at electrodes 61, 63, 68, 65, 67, 66, 62 and 64, respectively the electrodes 151, and it should be mentioned that six different potential levels are possible are, namely D, E and F, as well as their numerically equal values more opposite Polarity D ', E' and F '.

The figures lOd, lOe and lOf show states D, v and F of the figure lOd in detail.

FIG. 10 shows that the DC voltage component Y ', the is called ED-ES, with respect to the reference potential P is applied. When the potential difference ED -E5 is smaller than the threshold voltage of the liquid crystal for DC voltage operation, it does not light up. Figure lOe shows that the DC component X corresponding to ED + E5, with respect to the reference potential P is indicated. If the Potential difference ED + ES is greater than the threshold voltage of the liquid crystal in DC operation, the latter lights up. Figure lOf shows the high frequency pulses of amplitude 2 (ED + ES), which fluctuate around a potential which is around the value EF is higher than the reference potential P. If the value E is less than the threshold voltage of the liquid crystal, there is no display.

It can be seen from Figure 10c that the states D ', E' and F ' themselves only differ from the states D, E or F by their polarity, so that so the DC voltage component 'in the state D' has the value: - (ED-ES), while the equilibrium stress component Y in the state E 'has the value: - (ED-ES). figure 10b shows that the DC voltage components X and Y 'from the electrodes 61 to 68 run to the electrodes 151, while the DC voltage components X 'and Y run from electrodes 151 to electrodes 61 to 68, that is, vice versa.

In this way, when displaying the number 1234 with the liquid crystal display device 100 according to FIG. 7, only the number 4 is displayed in the first column. In a similar way The number 3 is displayed in column 2 and number 2 in the column 3 and the number 1 in column 4, Figure 10c shows the relationships between the boosted voltage 2ED of amplifier 85 and boosted voltage 2ES of Amplifier 86, each distributed on the basis of the potential Eg as shown where the voltage 2E5 is lower than the voltage 2ED As before Described in detail, the electrodes form transparent conductive films two transparent supports, with the electrode on one support in a number Electrode segments is subdivided, with one lead from each electrode segment leads to the edge area of the transparent carrier and so many electrode segment groups are provided as are necessary to display the information.

The same electrode segments in different groups are in each case with one another connected so that such a structured liquid crystal display panel does not Can only be used with a dynamic driver system, but also simply structured is. Since the electrode segments are on the outside, i.e. the edge area of the transparent The carrier are connected to one another, the width of the electrodes and the lines in the be chosen essentially the same, so that scoreboards are different Size can be made relatively small compared to known Vorrichtuen can.

Since a smaller number of external connecting lines is also required is, in the illustrated embodiment, a total of 12 connecting lines, and while 4 for the columns and 8 for the electrode segments, the reliability will be the liquid crystal display device is thereby enlarged considerably.

In the liquid crystal display device according to the invention, a driver system for matrix-like excitation can be used, which is a first Driver circuit includes that of high frequency pulses with a higher frequency when he switched frequency of the liquid crystals and with low frequency pulses with a lower frequency than the switching frequency of the liquid crystals and controlled by line input signals. There is also a wide driver circuit provided, which are precontrolled by low frequency pulses and by segment control signals is controlled. The high-frequency pulses become the output pulses of the second Driver circuit superimposed, wherein the driver voltage has a lower level than the first-mentioned driving voltage. Because while the liquid crystals are lit up is fed with alternating current, the life of the liquid crystals can be significantly extend, and since the transition from the luminous state to the dark state under one High frequency excitation takes place at a higher frequency than the switching frequency of the liquid crystals, the switching properties of the liquid crystal become essential improved. Since the driving voltage of the liquid crystals is in the range of 20 to 30 volts, a very low power consumption can be achieved by using integrated Achieve circuits.

Claims (7)

Claims 1. Liquid crystal display device having liquid crystal cells that each have two dielectric carriers arranged in parallel at a distance from one another, which are each coated with conductive layers and between which a liquid crystal is included, wherein at least one carrier with the conductive layer located thereon is optically transparent, and with a driver circuit for the liquid crystal cells, d a d u r c h e k e n n n z e i c h n e t that the one conductive layer on the one Each liquid crystal cell supports a number of electrode segments (61 to 68) is subdivided, the connecting tracks to an edge region of the associated Support run that mutually corresponding electrode segments of all liquid crystal cells are connected to each other at the edge area that the conductive layer on the another carrier of each liquid crystal cell forms a collecting electrode (151), and that the driver circuit has an output for each electrode segment group and one Has output for each collecting electrode. 2. Apparatus according to claim 1, d a d u r c h g e X e n n -z e i c h n e t that the electrode segments are interconnected by traces of the conductive layers are connected. 3. Apparatus according to claim 1, d a d u r c h g e k e n n -z e i c It hLn e t that the electrode segments are connected to one another by conduction paths are, with a conductive binder (40) are applied and to the At intersections with other electrode segments, an insulating means (50) as an intermediate layer exhibit. 2. Apparatus according to claim 1 to 3, d a d u r c h g e -k e n n z e i c h e t that the driver circuit comprises a threshold driver circuit (76), which except from the control signals of high frequency pulses with a higher frequency as the switching frequency of the liquid crystals and of low frequency pulses with a frequency lower than the switching frequency of the liquid crystals is, as well as a second control circuit (30), which of the segment control pulses as well as the each frequency pulses is controlled and whose output signals the Iiochfrequenzimpulse are superimposed. 5. Apparatus according to claim 4, d a d u r c h g e k e n n -z e i c h n e t that the drive voltage generated by the second driver circuit (30) is smaller than the voltage generated by the first driver circuit (76). 5. Apparatus according to claim 4 or 5, d a d u r c h g e -k e n n z e i c h n e t that the first driver circuit (76) is from a pulse generator (75) is controlled, which in turn is controlled by a clock generator (70). 7. Apparatus according to claim 6, d a d u r c h £ e k e n n -z e i c n e t that the clock generator (70) also has a counter (74) and a register (71) controls, the outputs of which feed a converter (73), which in turn feeds the inputs the second driver circuit (30) controls. Blank page