CH620036A5 - Liquid-crystal display device and use of the device as an oscillograph - Google Patents

Description

The invention relates to a liquid crystal display device with a control device and a liquid crystal element, which contains a two-dimensional matrix consisting of row electrodes, Zy (y = 1, ... N), and column electrodes Sfi ([x = 1, ..., M), where pro Column only one mi matrix element is displayed and this matrix element is always displayed when the difference between the signal voltages applied to the corresponding row electrode, Zy, and the respective column electrode, S (x, is zero, while the difference between the signal voltages between the corresponding 55 of the row and column electrodes of all other matrix elements have an effective value other than zero The invention further relates to the use of the liquid crystal display device as an oscillograph.

A liquid crystal display device of the type mentioned above is known from DE-OS 2 414 608. In this known device, the respective difference in the signal voltages between the row and column electrodes of the matrix elements not to be displayed has the effective value Veft = V2 / N • V, where V means the respective row or column peak w voltage. The larger the number of lines used, the smaller the effective voltage for a given value of V. On the other hand, this means that for a given value Veff with increasing number of lines, the voltage V must have an ever larger value. The same applies to the voltage at the driver circuits assigned to the row and column. Since such circuits are generally formed by integrated circuits (IC's) and can only be loaded with voltages of <20 V, the known devices inevitably limit the maximum number of rows used.

The object of the present invention is therefore to provide a display device of the type mentioned in the introduction, in which the increasing number of rows N does not necessarily also require an increase in the voltage V across the rows and columns.

According to the invention, this object is achieved in that a signal voltage which is independent of the display signal to be displayed is applied to each of the N row electrodes, Zy, that these signal voltages form an orthogonal function system with the same effective value in each case, that on each of the M column electrodes, S | i , is also one of the row signal voltages, and that the assignment of this signal voltage to the respective column electrode, Sji, is controlled by the display signal to be displayed.

Walsh functions are particularly suitable as signal voltages. On the one hand, they form an orthogonal function system and, on the other hand, they allow the use of integrated digital circuit arrangements.

The device has proven particularly useful as an oscillograph for displaying processes that can be changed over time.

Further advantages and possible uses of the invention result from the following description of exemplary embodiments in conjunction with the accompanying drawings.

It shows:

1 shows a circuit arrangement for generating Walsh functions for the row and column control of liquid crystal elements which are operated according to the invention;

FIG. 2 shows a control device consisting of several circuit arrangements according to FIG. 1 for operating a liquid crystal element according to the invention having 256 row electrodes.

The Walsh function generator shown in FIG. 1 consists of an 8-bit binary counter 1, eight AND gates 2, an exclusive OR gate 3 and a shift register 4, the parallel outputs of which are connected directly to switching stages 5.

If a first clock signal, TS [, is applied to the input K of the binary counter 1, eight different signals are obtained at the eight outputs of the counter, which have the function curve of Walsh functions. At the output A, for example, the function wal (1, t) is obtained; at output B the function wal (3, t); ...; and finally at the output H the function wal (255, t). These signals each arrive at an input of the AND gates 2. Depending on the binary data signals which are at the respective second input of the AND gates (in FIG. 1, these inputs are labeled a to h), the Walsh Functions passed through these gates and arrive at the exclusive OR gate 3. At its output, there is also a Walsh function, namely exactly one of the 255 possible functions wal (1, t), wal (2, t), ..., whale (255, t). The instantaneous value of this Walsh function, determined by the respective state of the 8-bit counter 1, during a time interval determined by the clock, is then stored in the shift register 4. This process is repeated cyclically for several data signals. The values of the Walsh functions are written in with the aid of a second clock signal, TS2, which is fed to the input L and runs synchronously with the data signal change. In the present case,

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for example, one of four commercially available, 8-bit shift registers connected in series, so that after 32 clock signals, register 4 is full. Each stored Walsh function value is assigned exactly one corresponding data signal.

In the cycle of the first clock signal TSj, the entire content of the shift register 4 is transferred in parallel to a switching stage 5 which acts as a buffer. This switching stage is in turn connected to the row or column electrodes, Zy or Su, so that the signal values stored in the switching stage are also present at the row or column electrodes.

The clock signal TS! also causes the 8-bit counter to continue counting, so that the process described above is repeated. If the shift register 4 is filled again, its content is again transferred to the switching stage 5 and its previous content is deleted.

In contrast to known Walsh function generators (see e.g. R. Kitai and CK Yuen: Walsh Function Generators, in: Walsh Functions and their Applications, IEEE 1974), it is neither necessary with the new circuit arrangement that the inputs a to h in Gray code-encoded data signals are still present, so that signals encoded in this way are supplied by counter 1. The circuit arrangement is therefore very simple compared to known arrangements. The fact that when using the new Walsh generator a binary input value j is not necessarily assigned an output value wal (k, t) with k = j does not bother. Because according to the invention it is not necessary to carry out row addressing in such a way that the Walsh function wal (1, t) is located on the first row electrode, the function wal (2, t), etc. is located on the second. Rather, it is only necessary that exactly one of the functions wal (1, t) to wal (255, t) is located on each row electrode; For example, the function wal (3, t) on the first row electrode, the function wal (230, t) etc. on the second electrode and that this assignment of the Walsh functions to the individual row electrodes does not subsequently change.

The circuit arrangement shown in FIG. 1 can either be assembled from 8 standard CMOS integrated circuit arrangements (one 8-bit counter, 2 x four AND gates, one exclusive OR gate (eg RCA CD 40101B parity checker) four 8- bit shift registers with switching stages (eg RCA CD 4094B bus register) or as a single IC with 44 connections.

FIG. 2 shows how a plurality of such circuit arrangements (modules) shown in FIG. 1 can be combined to control a liquid crystal element: This liquid crystal element 6 may have, for example, 256 row electrodes Zy, which are controlled by eight modules, Mt to M8. The two first inputs of a module correspond to the inputs L and K according to FIG. 1; The clock signals TS! and TS2 supplied. The remaining eight inputs of a module correspond to the data inputs a to h according to FIG. 1. The (32 each) outputs of the modules are identical to the outputs of the switching stages 5 shown in FIG. 1.

Three of the eight data inputs of each module are hardwired, i.e. there is a constant binary signal at these inputs, in such a way that the combination of the signals at these inputs is different on each module. There are therefore a total of 8 possible combinations and therefore a maximum of 8 modules can be used in this case, with which 8 • 32 = 256 Walsh functions can then be generated. The remaining data inputs are connected to a 5-bit counter 7.

The clock signals TS2 are generated with the help of a clock generator 8? generates signals with a frequency of about 526 kHz. These signals TS2, in addition to the modules M, to M8, etc. also the 5-bit counter 7 clocked. The clock signal TS, can then be taken from one of the outputs of this counter, the frequency of this signal being 1/32 that of the m signal TS2.

The arrangement described above controls each row electrode Z with exactly one Walsh function wal (k, t), which is different and orthogonal to the signals at all other row electrodes. Furthermore, the input signal, which determines the respective Walsh function on the line Zy, corresponds to the binary coded number of lines y, which in turn corresponds to the position (height) of the line.

To control the column electrodes, modules M 'to M'jj ([1 can also be greater than 8) are provided, which in turn correspond to the circuit arrangement according to FIG. 1. The binary data are retrieved from the read / write memories 9 assigned to the modules. In the exemplary embodiment described here, these memories are each with 32 addresses and 8 data inputs and 8 data outputs (32 X 8 RAM).

The 8-bit words assigned to the addresses correspond to the values to be displayed. These are generated via an analog-digital converter, not shown in FIG. 2. The analog measured value to be displayed is thus converted into | x X 32 words with a length of 8 bits using this converter and these words are then written into the memories 9 one after the other. After the write process, the addressing inputs of the memories are connected to the outputs of the 5-bit counter 7 vs. The stored 8-bit data words are then read out cyclically according to the respective status of this counter. The modules M '[through M' ^ then supply the column electrodes with signals which have a Walsh function profile, the respective Walsh radio function being characteristic of a specific amplitude value of the analog signal to be displayed. Since each Walsh function is assigned to only a single row electrode, there is only one matrix element per column, in which the potential difference between row and column electrodes is zero. All other matrix elements in this column have a voltage of 0.707 U. The analog signal to be displayed is therefore represented on the liquid crystal element 6 as a trace of unexcited matrix elements, the level of the signal displayed being proportional to the amplitude of the analog signal.

It can also be seen from FIGS. 1 and 2 that the number of integrated circuits which are necessary for the construction of such an oscillograph can be reduced if the length of the shift register 4 per module is increased. If, for example, instead of 32-stage shift registers, those with 64 stages are used. In this case, the number of modules required would be reduced by a factor of 2 for a given number of columns and rows. However, higher-level shift registers also require higher clock frequencies TS. m) Another limitation arises from the fact that the number of connections per module cannot be chosen arbitrarily large.

2 sheets of drawings

Claims (6)

620 036 PATENT CLAIMS 1. Liquid crystal display device with a drive device and a liquid crystal element, which has a two-dimensional row electrodes, Zy {y = 1,. . N), and column electrodes (S (i (ji = 1,.. M) contains existing matrix, whereby only one matrix element is displayed for each column during operation, and this matrix element is always displayed when the difference between the signal voltages of the corresponding Row and column electrode is zero, while the difference of the signal voltages between the corresponding row and column electrodes of all other matrix elements have a non-zero effective value, characterized in that a signal voltage which is independent of the display signal to be displayed is applied to each of the N row electrodes, Zy that these signal i voltages form an orthogonal function system with the same effective value in each case, that each of the M column electrodes, S (i, is also each one of the row signal voltages, and that the assignment of these signal voltages to the respective column electrode, S [A, by the display signal to be displayed is controlled. 2. Liquid crystal display device according to claim 1, characterized in that the signal voltages are Walsh functions. 3. Liquid crystal display device according to claim 2, characterized in that for generating the Walsh functions circuit modules (Mt ... Ms; M '| ... M' ^) are used, which consist of one or more binary counters ( 1) exist, the assignment of the respective Walsh function to the binary data signal using an exclusive-OR gate (3). 4. Liquid crystal display device according to claim 3, characterized in that the same circuit modules (M [... M8; M ',... M'n) both for controlling the column electrodes (Sji) and for controlling the row electrodes .i (Zy) can be used. 5. Liquid crystal display device according to claim 4, characterized in that in each case a plurality of circuit modules (M! ... M8; M ', ... M'n) are used to control the columns * and row electrodes. 4th 6. Use of the liquid crystal display device according to one of claims 1 to 5 as an oscillograph.