DE3814816A1 - Method for controlling display devices - Google Patents

Abstract

In a method for controlling display devices with picture elements, arranged in the shape of a matrix, and non-linear series elements, line multiplex signals being fed to conductors forming the lines of the matrix, and column multiplex signals being fed to conductors forming the columns of the matrix, the picture elements of in each case one line being controlled simultaneously and the picture elements in each case assigned to a column being controlled one after the other within a predetermined period and the respective picture elements being furthermore controlled or not controlled as a function of the absolute value of the respective difference between the line multiplex signals and column multiplex signals, the sign of the difference is changed a plurality of times during the predetermined period.

Description

The invention relates to a method for control of display devices with a matrix pixels and non-linear ballasts ten, being at conductors which are the rows of the matrix form, line multiplex signals and to conductors which form the columns of the matrix, column multiplex signa le be created, z. B. the pixels each because one line at a time and one at a time Column assigned pixels one after the other inside can be controlled within a predetermined period and further depending on the amount of respective difference between the line multiplexing gnalen and column multiplex signals a control or no control of the respective pixels he follows.

In these known methods for driving display devices - in particular those with liquid crystal elements - the individual electrodes, which represent the pixels, are connected upstream of non-linear elements. These have the highest possible resistance at never-occurring voltages and become conductive at higher voltages. An example of these elements are so-called MIM elements, in which an oxide layer is provided between two metal layers.

The task of these nonlinear elements is to create a Charging the from the electrodes of the respective picture point formed capacitor if the Pixel is controlled, and during the control maintenance of the other pixels to allow the cargo. During control the other pixels are known method at the uncontrolled pixel a voltage of opposite polarity that is less than the voltage to drive, however because of an existing residual conductivity linear elements to discharge the uncontrolled th pixel contributes. Through this discharge who the strip running in the column direction bar, which depend on the respective image content.

The object of the invention is to provide a method for Control of display devices with matrixför mig arranged pixels and non-linear Vor to specify switching elements with which the named Disadvantages are avoided.

The method according to the invention is thereby characterized records that within the given period several times a change in the sign of the difference he follows. The sign is preferably used change in time with the line advance. It is however also possible after a small number of  Line sign to change the sign.

It is already known, after each activation er all pixels, i.e. after writing one Image to reverse the voltage to a span to achieve smooth control. This solves however not the above task.

The charge according to the invention of the uncontrolled pixels during the on control of the other pixels largely obtained Basically, by using the no additional method according to the invention generated high-frequency spectral components, of which an additional interference radiation can go out.

According to a development, the invention Process in an advantageous manner with the known Methods are combined in that in addition to line-by-line change of sign from given a period for a given period change to DC voltage compensation.

The invention allows numerous embodiments. One of them is shown schematically in the drawing shown several figures and below be wrote. It shows:

Fig. 1 is a circuit diagram of a portion of a display device having a matrix form angeord Neten pixels,

Fig. 2 are timing charts of the driving voltage of a pixel according to the known method,

Fig. 3 are timing charts of the driving voltage of a pixel according to the invention Ver drive,

Fig. 4 more time charts for known processes driving,

Fig. 5 further time diagrams for the inventive method and

Fig. 6 shows a circuit arrangement for performing the method according to the invention.

The same parts are the same in the figures Provide reference numerals. The terms row and column te become independent in the context of this patent application used by the orientation in space, they are only defined by the type of control.

Fig. 1 shows a section of a device with three pixels each in four lines. Conductors 1 , 2 , 3 , 4 in the column direction and conductors 5 , 6 , 7 in the row direction are used to control the pixels. The series circuit comprising a voltage-dependent resistor 8 and a capacitor 9 , which is formed by the electrodes of the respective pixel, is connected to a respective crossing point. Is voltage at one of the capacitors 9 , the pixel changes its color, for example black. The voltage-dependent resistors 8 can advantageously be formed by MIM elements which become conductive at a predetermined voltage. For the selective control and charging of the individual pixels or capacitors, it is therefore necessary to supply signals via the conductors 1 to 7 , which have a correspondingly high differential voltage at the pixels to be controlled and a lower voltage at the pixels not to be triggered.

In the following explanation with reference to FIG. 1 it is assumed that with a normalized voltage difference of 2, the MIM elements 8 become conductive and thus enable capacitor charging, while with a voltage difference of less than 2 the MIM elements are non-conductive. Fig. 1 shows the processes during three clock periods T 1 , T 2 , T 3 , the voltages on the conductors 1 to 7 being shown during the three clock periods. During a first clock period T 1 , the voltages 2, 0, 0, 2 are present on the horizontal conductors 1 to 4 . The vertical conductor 5 is supplied with the voltage 0, while the vertical conductors 6 , 7 are connected to a voltage of 1.

Accordingly, the voltage at the pixels 11 and 41 is one during the first clock period T 1 , while the voltage difference is smaller at all other pixels. Thus, only the pixels 11 and 41 are driven, that is, their capacitors 9 are charged, which is highlighted by hatching.

In the next clock period T 2 , the voltages supplied to the conductors 1 to 4 have the same values, while the conductors 5 and 7 are now at the voltage 1 and the conductor 6 is at 0 V. In this clock period, the pixels 12 and 42 are driven. In the third clock period T 3 finally, the conductors 5 and 6 are supplied with the voltage 1, while the conductor 7 is at 0 V. All vertical conductors 1 to 4 are subjected to a voltage of 2, so that the pixels 13 , 23 , 33 , 43 are driven. The respectively controlled pixels are represented by hatching the capacitor.

After all lines have been activated, begins a new cycle at the first line. This specified The following period is based on the Television technology called image period.

Fig. 2 shows the course of the voltage Uxy at one of the pixels in the control according to the known method during two image periods. In line a) the case is shown that the picture element, to which the voltage curve relates, is switched on, while all the other picture elements of the same column are switched off. In the case shown in line b) it is assumed that all picture elements of the same column are switched on. During the period between t 0 and t 1 , a voltage of 19 is applied to the picture element, this causes the MIM element to become conductive and the capacitor to be charged to the voltage Ulc shown in broken lines .

Between the time t 1 and the time tn who the other picture elements of the same column are driven, a voltage of -3.5 V being present at the picture element of line 1 . This causes the remaining drop in the voltage Ulc via the residual conductivity of the MIM element , so that at the end of the time period from t 0 to tn (image period) the voltage and thus also the contrast of the image elements are lower than at the beginning of the image period. In the following image period between the time tn and t 2 n , the control takes place with reversed polarity, but this results in a reduction in the contrast in the same sense.

If the remaining picture elements of the same column are switched on, a voltage greater than +3.5 V results during the time from t 1 to tn, so that there is almost no drop in the voltage Ulc .

Fig. 3 shows the voltage that a) if the other pixels of the column 1 off, and b) if all the pixels of column 1 are turned on. During the time from t 1 to tn there is a meandering voltage between 3.5 V and -3.5 V between the cases a) and b), only a phase shift can be determined. The discharge of the picture element shown in FIG. 2 is thus practically independent of the control of the other picture elements of the same column.

In addition, the drop in the voltage Ulc is less pronounced since the voltage at the picture element is negative only for part of the time between t 1 and tn .

A case is conceivable in which, in the column direction, every second pixel is switched on and the pixels in between are switched off, so that even when using the method according to the invention, a discharge according to FIG . In the case of the information which is usually to be displayed using dot matrix display devices, however, the occurrence of such image content is not likely or is not intended at all.

Figs. 2 and 3, the voltages are at an image point, the calculations as the difference between the tension occurring at the intersecting conductors. FIGS. 4 and 5 show both voltages at the Lei tern and the difference resulting voltages to some of the pixels. Here, Fig. 4, the known and FIG. 5 Ver the inventive drive. The signals shown in the diagrams a, b and c each are supplied to the conductors in rows Rich tung, for example, the conductors 1, 2, 3 (Fig. 1) . Diagrams d) and e) show two multiplex signals with which columns are applied to the conductor.

The further diagrams show the difference signals resulting from the column and row multiplex signals at the pixels, the position of which is indicated in detail. For example, the pixel in row 1 , column 1 is switched on, while the pixels in column 1 in rows 2 and 3 do not achieve the voltage required for switching on. Of the three pixels in column 2 , the one in row 2 is switched on, while the other two are switched off.

The diagram a) can be seen that in the Darge presented example, only the pixel in column 1 is turned on, while the pixels in column 2 to N are turned off. The same process is repeated with the opposite sign. Both image periods together are designated by the period T in FIGS. 4 and 5.

Like FIG. 3, FIG. 5 also shows that the voltage curve at one pixel is practically unaffected by the state of the further pixels in the same column as a result of the method according to the invention.

FIG. 6 shows an arrangement for driving a liquid crystal display 51 with MIM elements, in which 128 rows and 160 columns are provided. This corresponds to a number of 20 480 pixels. The individual components of the arrangement according to FIG. 6 are known per se and need not be explained in more detail in order to understand the present invention. A controller 52 , which is commercially available under the designation HD 61830, is used to control the timing of the control signals. The voltages to be supplied to the conductors in the individual time segments are generated in a voltage supply unit 53 . From the control ler 52 switching signals are fed to the line drivers 54 to 57 , which are also available in the trade.

Controlled by the switching signals, the voltages V 1 , V 2 , V 5 , V 6 generated by the voltage supply unit 53 are supplied via the line drivers 54 , 55 as multiplex signals in accordance with FIG. 5. The multiplex signals for the column lines are generated using the column drivers 56 , 57 from the voltages V 1 , V 2 , V 3 , V 4 . A crystal oscillator 58 with a frequency of 1.5 MHz is used to generate the clock for the controller 52 . The data generated by the controller 52 during the program run can be temporarily stored in a read-write memory 59 . For higher-level control of the controller 52 , a main processor unit (MPU) 60 is provided, which is connected to the controller 52 via corresponding data lines, control lines and via an address decoder 61 . Via an input unit 62 , the main processor unit 60 can be supplied with various commands, such as start, stop, positive, negative or reset.

Claims (4)

1. A method for controlling display devices with pixels arranged in the form of a matrix and non-linear ballast elements, line-multiplexed signals being applied to conductors which form the rows of the matrix and column-multiplexed signals being applied to conductors which form the columns of the matrix, the pixels being in each case one line at the same time and the pixels assigned to each column are controlled one after the other within a predetermined period and, furthermore, depending on the amount of the respective difference between the line multiplex signals and column multiplexed signals, there is activation or no activation of the respective pixels, characterized in that within the sign of the difference is changed several times during the specified period. 2. The method according to claim 1, characterized in net that the change of sign in time with the Line advancement takes place. 3. The method according to claim 1, characterized in net that the change of sign after each a few line cycles. 4. The method according to any one of the preceding claims che, characterized in that besides the lines indicate change of sign from the given one Period for a given period a change of sign sel for DC voltage compensation.