NL194875C - Display device containing a liquid crystal material. - Google Patents

Description

1 194875

Display device containing a liquid crystal material

The invention relates to a display device comprising a liquid crystal material between two supporting plates held at a defined distance from each other with surfaces facing one another, a pattern of N line electrodes on one surface and a pattern of column electrodes on the other surface wherein the line electrodes intersect the column electrodes and thus display elements are formed at the intersections and the device comprises a control circuit for applying block-shaped data signals to the column electrodes and a line scanning circuit for periodically scanning the line electrodes and applying block-shaped 10 line selection voltage signals, wherein during the frame time of the periodic scanning of the line electrodes a plurality of lines n are simultaneously selected during a selection time wherein the line selection voltage signals to be supplied are different during the selection time are for each of the lines to be selected simultaneously, the amplitudes of the line selection voltage signals being equal for each of the lines to be selected simultaneously, and wherein the line selection voltage signals to be supplied of the lines to be selected simultaneously are mutually orthogonal.

Such a display device is known from T.N. Ruckmongathan, "generalized addressing technique for RMS responding matrix LCDs", pp. 80-85, IEEE Conference Record of the 1988 International Display Research Conference. An addressing method is described in which more than one addressing line is selected at a time. As a result, a lower voltage is required than usual until then, and a better brightness uniformity is achieved than usual up to then.

The invention has for its object to further improve the known display device, and for this purpose is characterized in that the selection time for a group of a number of n lines is split into a number of selection time intervals which are distributed over the frame time such that the sum of these time intervals is equal to the selection time and such that during the scanning of the N lines no more than n lines are selected simultaneously, wherein for each of the lines to be selected simultaneously the selection voltages to be supplied during these time intervals are identical to the parts of the original line selection voltage signals of the relevant lines that correspond to the relevant time intervals.

A high contrast and high brightness are hereby achieved, while at the same time fast switching times are possible.

In an embodiment of the display device according to the invention, an odd number of lines is selected during a selection time.

In an alternative embodiment of the invention, an even number of lines is selected simultaneously during a selection time, one of the line selection voltage signals to be supplied being a unipolar voltage, existing for a period equal to the selection time, and the other line selection voltage signals of alternating polarity.

Here, the other line selection voltages of alternating polarity preferably have the lowest possible frequency.

Further or instead, in one embodiment, the selection duration is split into a number of 40 time intervals of equal time duration such that the sum of these time intervals is equal to the selection time, these time intervals being distributed over the frame time and wherein during the scanning of the N line matrix no more than n lines are selected simultaneously, the line selection voltages to be applied to each of the lines to be selected simultaneously being identical during these time intervals to the corresponding parts of the original line selection voltage signals of the relevant lines. In an embodiment of the display device according to the invention, and in particular with an even number of simultaneously selected lines, 2, 4 and 8 lines are selected simultaneously.

in an embodiment of the display device according to the invention, and in particular with an odd number of selected lines, the selection duration is split into equal time intervals which are equally distributed over the frame time.

In an embodiment of the display device as described above, the amplitude Y 'of the line selection voltages with simultaneous selection of n lines is given by Yn = N, / 2 * Χ, / η, where Xn is the maximum data voltage occurring in the data signals , and wherein Xn is given by

Yn = n1 / 2 * V! * (0.5 / (1-N'1 / 2)} 1/2 with \ / Λ equal to the threshold voltage or the effective RMS voltage value of a display element 55 in the "off" state.

In a further embodiment of the display device, the number of lines N of the matrix is not a multiple of the number of simultaneously selectable lines n, an additional number of virtual or dummy 194875 2 lines nv is assigned to the matrix such that the sum of N and nv is a multiple of n, and the 'amplitude Y' of the line selection voltages for simultaneous selection of n lines is given by Yn = N1 / 2 * XJn, where Xn is the maximum data voltage occurring in the data signals, and Xn given is X n = n1 / 2 * V, * {0.5 (1-N'1 / 2)} 1/2, 5 with V, equal to the threshold voltage or the effective RMS voltage value of a display element in the "off" -status.

The invention is elucidated with reference to the accompanying drawings, in which figure 1 schematically shows a part of a matrix-oriented display in direction; Figure 2 schematically shows a transmission voltage characteristic from one to the display device of figure 1; Fig. 3 schematically shows the transmission behavior during a frame time of a display element in the "on" state; Fig. 4a shows voltage forms for the line signals and data signals during field scan with simultaneous selection of two lines; Fig. 4b shows resulting voltages across pixels 1 to 8 of Fig. 4a; Fig. 5a shows for a matrix of 10 lines, the scanning cycle in which the addressing time tg is not split; Fig. 5b shows a matrix of 10 lines, the scanning cycle in which the line selection time ta is split into two time periods ta / 2; Fig. 5c shows a matrix of 10 lines for comparison, the control scheme according to the standard RMS multiplex method with selection of a single line; Figure 6a shows voltage forms for driving an N line matrix when 4 lines are selected simultaneously during the field scan; Figure 6b illustrates how the data signals can be determined to write the information of Figure 6a; Figure 7 shows the resulting voltages for elements 1 to 22 of Figure 6a; Fig. 8a shows the scanning cycle in which the line selection duration tb has not been split for a matrix of 12 lines; Fig. 8b shows the line selection time tb split into four time periods J4 which are equally distributed over the frame time; Figure 9 shows line selection voltages with simultaneous selection of eight lines.

Known display devices are usually operated in multiplex control according to the so-called RMS-35 mode.

The method of control (based on the so-called RMS behavior of the liquid crystal material) is described, inter alia, by Alt and Pleshko in I.E.E.E. Trans. El. The V. ED 21, 1974, pp. 146-155, by Nehring and Kmetz in I.E.E.E. Trans. El. The V. ED 26, 1979, pages 795-802, and by Kawakami et al. In SID-IEEE Record of Biennal Display Conference, 1976, pages 50-52.

This method of driving is considered to be the most common for driving liquid crystal display devices that are constructed as a matrix of pixels as described above, wherein no active electronic switch (such as, for example, thin-film transistor) is used per pixel.

With this method of driving, the pixels are switched from a first state to a second state optically different therefrom with the aid of the line scanning circuit which periodically scans the line electrodes with a line selection pulse of Vs and with the aid of the control circuit for applying data signals to the column electrodes which supply data voltages of +/- Vd to the column electrodes during a time that a line electrode is scanned, such that the optical condition realized in a display element is determined by the so-called 50 Rooth-Mean-Square (RMS) voltage value over the relevant element.

The RMS voltage value V2 for the selected display elements, i.e. the display elements in the on state, is given by: V22 = (Vs + Vd) 2 / N + (N - 1) * Vd2 / N (1)

The RMS voltage value Vn for the unselected display elements, ie the display-55 elements in the off state, is given by: V, 2 = (Vs - Vd) 2 / N + (N - 1) * Vd2 / N (2)

Figure 2 schematically shows a transmission voltage characteristic of an image cell belonging to this m 3 194875 display device.

Alt & Pleshko have derived relationships that, for a given value of the ratio S = (also called threshold steepness in the transmission voltage characteristic), represent how large the maximum number of lines is that can be controlled with this method while maintaining a predetermined contrast and in which way the voltage Vs of the line selection pulse and the data voltages +/- Vd must be chosen to realize this. These relationships are as follows: ^ = (^ + 1) / ^ - 1)} 2 (3) (ν, Λ / d) 2 = N ™ (4)

Vd2 = V, 2 * (0.5 / (1 - Q)} (5) where: Q2 = Nmax'1

If now the line selection voltage Vs and the data voltage Vd are selected in accordance with the expressions (2) and (3), when using lines the resulting RMS voltage over a selected pixel will be equal to V2 and the resulting RMS voltage over a non-selected pixel equal to Vv A larger multiplexing degree, i.e. a higher value for Nmax, requires a steeper slope in the transmission voltage characteristic, ie a value of the quantity S = Vg / V, closer to 1.0.

With the currently known (and already used) so-called 'SUPER-TWISTED' liquid crystal effects, very high values can be realized because the threshold steepness S of the transmission voltage characteristic of these effects has a value that is very close to the limit value 1.0 .

Figure 1 schematically shows a part of a matrix-oriented display device 1 with Nmax selection lines (row electrodes) 2, and describes the principle operation of the aforementioned RMS multiplex driving method.

The information to be displayed is provided on the data lines (column electrodes) 3. At the location of the intersections of the selection lines 2 and the data lines 3, the display elements 4 are located. Depending on the information presented on the data lines 3, the display elements 4 are located in an on state or off state:

The information is entered as follows.

Synchronous with the selection of the lines or row electrodes using the line selection voltage Vs 30 (which is selected according to the terms (4) and (5)), the image information (data voltage +/- Vd) is supplied via the column electrodes.

Thus, from the time t1 during a period t1 (also called line time), the line 28 is selected which together with the information then present on the data lines 3a, 3b, cc (ie: +/- Ν / ') the optical state of the pixels 4 ", 4" *, 4 °°.

During this period t, that the line 2 ° is selected, there is a voltage +/- Vd across all other pixels corresponding to the line electrodes 2b, 2C, etc.

From the time t2 (where: t2 -1, = tn), during the period t, the line 2b is selected. The information then present on the data lines 3 (i.e.: +/- Vd) determines the state of the pixels 458.

4bb 4bc 40 After this line time t, the next line is then selected. Thus the entire image is written in line-by-line. After the last line of the matrix is selected, the entire cycle is repeated (so-called "repeated scan procedure"). The duration of a single write cycle is called the frame time or frame time t,: t, = N * t, where N represents the number of lines that are thus successively scanned.

45 It is important with this RMS control method that both the rise time and the fall time (or the switch time for transition to the "on" or "off" state) of the optical effect are much larger than the frame time.

Under these conditions, the display element responds to the cumulative effect of a number of drive pulses (or selection pulses). Here, in particular, a liquid crystal display element reacts in the same manner as when it was driven with a sine wave or blck wave signal with the same RMS voltage value as that of the "on" and "off" voltages V2 and V given by the expressions (1) and (2).

As already discussed, the maximum number of selection lines Ν ^ χ is related to the value of the ratio V2 / V1 (threshold steepness).

55 As the degree of multiplex increases, higher and higher voltages are necessary when using the RMS multiplex driving method described above.

In particular, the line section voltage Vs will become high (the data or column voltage Vd must always be chosen to be smaller than the threshold voltage of the optical effect in this control scheme).

The high selection voltages have the result that the liquid crystal effect no longer responds to the RMS voltage value (RMS voltage average over a frame time), but that the pixel has an optical response which is determined by the '' instantaneous' voltage value that the relevant voltage element feels during the line selection time.

Figure 3 shows schematically the transmission behavior during a frame time of such a display element in the "on" - "state.

During the line time t, during which the relevant element senses a voltage of the magnitude of Vg + Vd, the "on" - state is already achieved, because the "on" switching time will become smaller or equal to this with sufficiently high voltages line time.

After selection, i.e. after the line time t1, the relevant pixel only feels a voltage +/- Vd that is smaller than the threshold voltage. This means that the relevant pixel will return to its "off" state for the remainder of the frame time. For simplicity's sake, it is assumed that this drop time (or "off" switching time) is of the same magnitude as the frame time.

This characteristic so-called "non-RMS" transmission behavior has been observed, inter alia, in liquid-crystal displays with Super-Twisted liquid-crystal configurations, and in particular in displays with very thin liquid-crystal layer thicknesses. It is a known fact that the switching times of a liquid crystal effect are highly dependent on this layer thickness. As the layer thickness becomes smaller, the switching time will decrease. See, inter alia, Okada et al. In SID Digest or Technical Papers XXII, 1991, pp. 430-433.

The outlined transmission behavior (often referred to as "FRAME RESPONSE") in Figure 3 leads to loss of brightness and contrast loss compared to a pure RMS-responsive liquid crystal effect.

The invention will be further elucidated with reference to a number of exemplary embodiments.

In the first exemplary embodiment (Figs. 4a and 4b), it is assumed that simultaneous selection of two lines takes place during the field scan.

For simplicity, it is assumed that the number of lines N of the matrix is a multiple of "two".

The selection time is now defined as the addressing time tg.

Figure 4a shows voltage forms for the line signals and the data signals that can be used to write the information as shown in this figure by means of the indications "on" and "off". After the addressing time ta, as shown in Fig. 4a, the following two lines are selected and the appropriate data voltages are applied to the columns according to the information to be written by means of a column control circuit. The frame time t1 is given in this example by: t1 = (N / 2) The line selection voltage signals of the two simultaneously selected lines are mutually orthogonal.

For the sake of simplicity, Figure 4a assumes that selection is made of two adjacent lines. However, this is not necessary. Each pair of lines of the N-line matrix can be selected simultaneously with this control method. Of course, each line will always be selected per frame time only during an addressing time tg.

40 As with standard multiplex control as described above, "repeated scanning" also takes place now.

The amplitude of the line selection voltage signals is +/- A for the two simultaneously selectable lines.

Instead of the drawn voltage forms for the two simultaneously selectable lines, it is also possible to select 45 voltage forms with a higher frequency. In this case, the data wave signals will have to be adjusted, and will deviate from those shown in Figure 4a.

The amplitude of the data voltages in Figure 4a that are applied to the columns during the addressing time tg to write the desired information is equal to +/- D during one half of the addressing time and 0 during the other half of the addressing time The actual shape of a 50 data voltage signal is determined by information to be displayed (ie: the pixels "on" or "off").

Figure 4a shows the four data voltage signals with which the possible information content of the relevant picture elements occurring on the selected lines can be realized using the drawn line selection voltage forms: ie the combination "off" / "off" (column 1), "off "/ 55" on "(column 2)," on "/" off "(column 3)," on "/" on "(column 4).

The pixels 1,2, 5, 7 of the matrix shown in Fig. 4a are assumed to be in the "off" state; the pixels 3, 4, 6, 8 are in the "on" state.

5, 194875

In order to prevent direct voltage components, for example, the line selection voltages and the data voltages can be changed in polarity after each field time (analogous to the standard Alt & Pleshko multiplex control).

For the sake of simplicity, such a polarity change is not shown in Figure 4a.

Figure 4b shows the resulting voltages across the pixels 1 to 8 of Figure 4a during the addressing time ta. The resulting voltage is derived as the difference voltage VHjn -

Vkolom ·

Fig. 4b shows that the RMS voltage values during the addressing time tg of the pixels 1, 2, 5, 7 that are in the "off" state are equal to each other.

Similarly, the RMS voltage values during tg of the "on" elements are equal to each other.

With the help of Figure 4a, it can be verified that any "on" element and "uif element in the matrix has the same RMS voltage value during the remainder of the frame time (i.e.: during t, -ta).

The following expression can be derived for the RMS voltage value Vaan from an "on" element: Vaan2 = {ta '(A2 / 2 + (A + D) 2/2) + V (N / 2 - 1) * 02 / 2} / {νΝ / 2} (6)

The RMS voltage value Fills from an "out" element is given by the following expression:

Vult2 = (V (A2 / 2 + (A - D) 2/2) + ta * (N / 2 - 1) * D2 / 2} / {VN / 2} (7)

With the help of the "Lagrange Multiplier" technique, the maximum of Vaan can be determined as a function of the voltages A and D under the condition that Vui is equal to the threshold voltage V1.

The following expressions are then found: (A / D) 2 = N / 4 (8) D2 = V / * 2 * (0.5 / (1 - Q)} (9) where: Q2 = N'1

When equations (8) and (9) are substituted in the expressions (6) and (7), the Vaan / Vult ratio is found for: (Vean / VJ2 = {Q-1 + 1} / {Q-1) -1) (10)

With: Fills = V1 and the definition for the slope S = V2 / V1 it follows that expression (10) is in fact identical to expression (3) which represents the relationship between the number of lines to be multiplexed (in this exemplary embodiment: N) and the steepness of the transmission voltage characteristic.

If the expressions (8) and (9) are compared with the expressions (4) and (5), it follows that with the simultaneous selection of two lines the amplitude D of the data signals is a factor 21/2 greater than the required data voltage Vd according to the standard Alt & Pleshko RMS multiplex control (with the same number of lines N of the matrix).

The amplitude A of the line selection voltages with simultaneous selection of two lines is a factor 21/2 smaller than the required selection voltage Vs according to the standard Alt & Pleshko RMS multiplex drive (with the same number of lines N of the matrix). This means that the maximum voltage amplitude (A + D) of an "on" element in the above described control scheme with simultaneous selection of two lines is significantly smaller than the maximum voltage amplitude (Vs + Vd) for the same element when controlled according to the standard Alt & Pleshko principle.

40 Again consider the voltage forms of the line selection signals and the data signals of Figure 4a.

The full addressing time ^ is actually made up of two equal time periods \ J2 with associated characteristic voltage values for the line selection signals and the data signals.

In order to realize the desired Vane and Vuit RMS voltage values (according to expressions (8) and (9)), it is not necessary that the selection times t1 / 2 with associated voltages take place directly one after the other as assumed in the voltage forms in Fig. 4a .

The second selection time duration \ J2 can be selected, for example, from a time that follows half the frame time.

In figure 5 this is illustrated with the aid of a matrix of 10 lines. For the sake of simplicity, only the line selection voltage signals of the 10 lines are displayed during scanning of the matrix during a frame time.

Signed is the situation in which two adjacent lines are selected. As indicated earlier, this is not necessary. Figure 5a shows the scanning cycle in which the addressing time ta is not split. In Figure 5b, the line selection time L is split into two time periods tJ2, the second half of the total addressing time taking place from a time that is half the frame time. Figure 55c shows the control scheme according to the standard RMS multiplex method with selection of a single line for comparison.

It will be appreciated that for the scanning scheme as shown in Figure 5b, the control circuit for 194875 6 will need to adjust the data signals to apply the appropriate data voltages to the columns.

The principle of the scanning scheme according to Figure 5b is of course applicable not only to the drawn 10-line matrix, but to any matrix with an arbitrary number of lines N. For the case that N is not a multiple of two, matrix addressing can take place according to this principle by introducing a so-called "dummy" or virtual line.

The addressing scheme described in Figure 5b results in a drive where the single selection pulse of the standard Alt & Pleshko multiplex drive is replaced by two separate selection pulses with smaller amplitudes and occurring, preferably, at times equally distributed over the frame time. As already discussed, the maximum amplitude of the voltage across a pixel (during selection) is smaller with this driving method than with the standard Alt & Pleshko driving.

Both the occurrence of several selection pulses with a lower amplitude than the single selection pulse at the Alt & Pleshko control and the fact that the maximum voltage across a pixel during selection is smaller than the corresponding voltage at the Alt & Pleshko control scheme have a positive influence at reducing or eliminating "FRAME RESPONSE".

In the event that the above described control scheme with simultaneous selection of two lines and splitting the total addressing time ta into two separate selection time durations XJ2 as shown in sketch form in Figure 5b, is not sufficient to reduce or eliminate "FRAME RESPONSE", control can be selected whereby more than two lines are selected simultaneously, for example 4, or 6, or 8, etc.

However, it is not necessary for an even number of lines to be selected simultaneously.

The following exemplary embodiment (Figures 6a and 6b) describes how the control of an N-line matrix can take place when 4 lines are selected simultaneously during the field scan.

For simplicity, the number of lines N of the matrix is assumed to be a multiple of "four".

However, this is not necessary (in analogy with the control in which two lines are selected simultaneously, as already discussed).

The selection time is now defined as the addressing time t „.

Figure 6a shows voltage forms for the line signals that can be used to write the information as shown in this figure. For the sake of simplicity, only three columns i, j, k are shown in this figure 6a 30 with associated information content of the pixels 11 to 22 which correspond to the intersections of the columns i, j, k and the drawn first group of four lines that can be selected simultaneously. To illustrate the required data signals, the pixels 11, 12, 13, 14 associated with column i are assumed to be "off", "off", "on" and "off", respectively. The elements 15, 16, 17, 18 associated with column j are "on", "off", "off" and "on", respectively. The 35 picture elements 19, 20, 21, 22 associated with column k are "on", "on", "uif" and "on", respectively.

The following 4 lines are selected after the addressing time tb. The frame time t1 is given in this example by: t, = (N / 4) * tb.

The line selection voltage signals of the four simultaneously selected lines are mutually orthogonal, such that the selection signal of one of the four lines to be selected simultaneously has a half-period time 40 corresponding to the addressing time tb. In Figure 6a this is the first (top) line of the group of four lines that can be selected simultaneously. However, it is not necessary for this said line to have this line selection voltage form.

For the sake of simplicity, Figure 6a assumes that selection is made of four adjacent lines. However, this is not necessary. Every four lines of the N-line matrix can be selected simultaneously with this driving method. Of course, each line will always be selected per frame time only during an addressing time tj.

"Repeated scanning" takes place.

The amplitude of the line selection voltage signals is equal to +/- B for the four lines to be selected simultaneously. To prevent direct voltage components, for example, after every field time, the polarity 50 of both the line selection voltages and the data signals can be switched. For the sake of simplicity, this polarity change is not shown in Figure 6a.

Instead of the drawn voltage forms for the four simultaneously selectable lines, voltage forms with a higher frequency can also be selected. In this case, the data wave signals will have to be adjusted, and will deviate from those shown in Figure 6b.

Figure 6b illustrates how the data signals can be determined to write the information as shown in Figure 6a.

To this end, first consider the pixels 11, 12, 13, 14 associated with column i. Pixel 11 should be 194875, in the "off" state. To realize this, a data voltage signal should be supplied as selection signal for pixel 11 during selection that is in phase with the line selection signal of the corresponding selected line.

This signal is shown in Figure 6b in the column with the column "COLUMN i." The amplitude X of this signal (and the amplitude of the line selection signals) is determined by the requirement that the RMS voltage value of the "off" elements must have a defined value while the RMS voltage value of the "on" elements must be as large as possible.

Pixel 12 should be in the "off" state, and analogously to the above, the data voltage signal to be supplied during selection for pixel 12 should be in phase with the line selection signal of the corresponding line. This signal is shown in Figure 6b in the column with as. "heading" COLUMN i. The amplitude of this signal is equal to the amplitude of the above data signal for pixel 11.

Image element 13 must be "on". Therefore, a data signal during selection should be applied to pixel 13 which is in counter-phase with the line selection signal of the corresponding line.

This data signal for pixel 13 again has the same amplitude as the two aforementioned data signals of pixels 11, and 12, and is displayed in the column with "heading" COLUMN i. The data signal for pixel 14 during selection follows an analogous reasoning as given for the other pixels in the relevant column i.

Summarized, these four data signals produce the data signal as drawn in Figure 6b in the column 20 with "heading" COLUMN i.

This signal i is applied to the column i during selection of the four lines to which the elements 11,12,13,14 belong. The data signal to be supplied to column j can be determined in a completely analogous manner in order to realize the desired information content of the pixels 15, 16, 17, 18. Figure 6b illustrates all this with the voltage forms during selection for the relevant elements, as well as the total voltage (signal j) which is applied to column j during selection (see column with "heading" COLUMN j).

The column with "heading" COLUMN k illustrates the data voltage signals as well as the total voltage signal k for the relevant column k (see signed signals in the column with "heading" COLUMN k).

With simultaneous selection of four lines, data signals must be supplied in which 5 levels can be distinguished, namely +/- E, +/- E / 2, 0. The combination of these levels in a data signal is supplied to a column 1 during selection. determined by the image content of the elements in the relevant column I.

Fig. 7 shows the resulting voltages (defined as V, jn - V column) for the elements 11 to 22 of Fig. 6a during the selection time tt, using the line selection signals shown in Fig. 6a and the data signals (signal i, signal j , signal k) shown in Figure 6b. The RMS voltage values, during the selection time tb, of the "off" elements 11, 12, 16, 17, 21, 14 are equal to each other.

"The RMS voltage values of the" on "elements 15, 19, 20, 13, 18, 22 during the selection time t 1 are equal to each other.

After selection, and during the remainder of the frame time t, i.e., during t, -1 ^, the RMS voltage value of any "on" element is equal to the RMS voltage value of any "on" element.

The following expression can be derived for the RMS voltage value Vaan from an "on" element: 45 Vaan2 = {V (B2 + B'E / 2 + E2 / 4) + (N / 4 - 1) VE2 / 4} / (NV4) 01)

The RMS voltage value Vuit of an "off" element is given by the following expression: Vui, 2 = {tb * (B2 - B * E / 2 + E2 / 4) + (N / 4 - 1) VE2 / 4} / (N \ / 4) (12)

Provided Vuit = V1 Vaan can be maximized for given N as a function of B and E.

50 The maximum is found if: (B / E) 2 = N / 16 (13) E2 = 4 * V, 2 * {0.5 / (1-0)} (14) where Q2 = N'1

For the Vaan / Vuit ratio, the following is then found: 55 (Vaan / VuH) 2 = (O'1 + 1) / (0-1 - 1} (15)

With: Vuit = V, and the definition of the steepness S = V2 / V1, it follows that expression (15) is actually identical to expression (3) representing the relationship between the number of lines to be multiplexed (in this exemplary embodiment: 194875 8 N) and the steepness of the transmission voltage characteristic.

If the expressions (13) and (14) are compared with the expressions (4) and (5), it follows that with the simultaneous selection of four lines the amplitude E is a factor 2 greater than the required data voltage Vd according to the standard Alt & Pleshko multiplex control (with the same number of lines N of the matrix). The amplitude B of the line selection voltages with simultaneous selection of four lines is a factor 2 smaller than the required selection voltage Vs according to the standard Alt & Pleshko RMS multiplex drive (with the same number of lines N of the matrix).

Again consider the voltage forms of the line selection signals of Figure 6a and the voltage forms of the data signals of Figure 6b.

The full addressing time tj, is made up of four equal time durations ^ 4 with associated characteristic voltage values for the line selection signals and the data signals. To realize the desired Vane and Vuit RMS voltage values (according to expressions (11) to (14)), it is not necessary that the selection time periods t ^ / 4 with associated voltages take place directly one after the other as in the voltage forms in Fig. 6a and assumed in Figure 6b. The selection time durations with associated voltages 15 can occur distributed over the field time.

This is illustrated in Figure 8 using a matrix of 12 lines. For simplicity, only the line selection voltage signals of the 12 lines are displayed during scanning of the matrix during a frame time.

The situation is drawn in which four adjacent lines are selected simultaneously. As already indicated, this is not necessary. Fig. 8a shows the scanning cycle in which the line selection duration t * is not split. In Figure 8b, the line selection time tb is split into four time periods \ J4 which are equally distributed over the frame time. Other distributions are of course also possible, for example an equal distribution over the frame time of two selection times that are each equal to \ J2.

For the scanning scheme as drawn in figure 8b (but also for other distributions of the total line selection duration tb over the frame time, as indicated above), the control circuit for the data signals will have to be adapted to apply the appropriate data voltages to the columns. The principle of the scanning scheme according to Figure 8b with simultaneous selection of four lines and division of the total selection duration into smaller selection times (with associated voltages) that are distributed over the frame time is not only applicable to the drawn 12-line matrix, but to each matrix with an arbitrary number of lines N. For the case that N is not a multiple of four, matrix addressing with simultaneous selection of four lines can take place by introducing "dummy" or virtual lines. The addressing scheme shown in Fig. 8b results in a control in which the single selection pulse of the standard Alt & Pleshko multiplex control is replaced by four separate selection pulses with smaller amplitudes and occurring, preferably, at times equally distributed over the frame time. The maximum amplitude of the voltage across a pixel (during selection) is smaller with this driving method than with the standard Alt & Pleshko driving. As already discussed, with simultaneous addressing of four lines use can also be made, for example, of two separate selection times with the same duration t 2/2, which may or may not occur equally distributed over the frame time.

In the event that the above described control scheme with simultaneous selection of four lines and splitting the total selection time t "into four separate, equal selection times as sketchily shown in Figure 8b is not sufficient to reduce or eliminate" FRAME RESPONSE " a control must be selected in which more than four lines are selected simultaneously and the total selection duration is again split into a number of identical or different selection time periods, which may or may not be equally distributed over the frame time analogously to the manner as illustrated with the aid of the 45 control schemes wherein two or four lines are selected simultaneously.

On the basis of the descriptions given and explanation of the procedure to be followed for determining the correct control scheme with simultaneous selection of four and two lines, anyone who is somewhat familiar with this field can derive the line selection signals and the data signals which can be used with simultaneous control of other line numbers (other than two and four).

For the sake of completeness, in the third exemplary embodiment now to be given, line selection voltage signals are given in Figure 9 which can be used with simultaneous selection of eight lines. The selection signals in Figure 9 are again orthogonal, and one of the voltage signals used has a half period time corresponding to the addressing time (selection time). The data signals that are used in combination with these line selection signals can be determined according to the principle described in the control of a matrix with simultaneous selection of four lines (see, inter alia, figure 6b and associated text).

With the line selection signals of Fig. 9, again smaller selection times can be defined than the total selection time tc shown in this figure. For example, eight selection times the size of

Claims (9)

9, 194875, V8. These eight selection times can, for example, be equally distributed over the frame time in analogy with the descriptions of the distributions in Figure 8b and Figure 5b. Of course, the amplitudes of the line selection voltages and the maximum amplitudes of the data signals should be chosen such that the ratio of the resulting RMS voltage values of an "on" element and an "off" element: Vaan / Vuit is maximum at Vuit = V ,. With simultaneous selection of n lines, the amplitude Yn of the line selection signals, and the maximum amplitude Xn of the data signals should be chosen according to: Yn = N1 / 2 * Xn / n (16) 10 Xn n1 / 2 * V, * { 0.5 / (1 - Q)} 1/2 (17) where: Q2 = N'1 The table below illustrates for a number of values of n, how many and which voltage levels can occur in the data signals that in combination with line selection signals of which the shape is indicated in the exemplary embodiments given above, will lead to a desired image content. 15 n = 2: +/- X2, 0 n = 3: +/- X3, +/- Xg / 3 n = 4: +/- X4, +/- X4 / 2, 0 n = 5: +/- X5> +/- 3 * Xs / 5, +/- X./5 n = 6: +/- Xe, +/- 4 ^ / 6, +/- 2 * Xe / 6, 0 20 etc. A display device comprising a liquid crystal material between two support plates with facing surfaces spaced apart at a defined distance, with a pattern of N line electrodes on one surface and a pattern of column electrodes on the other surface, the line electrodes intersecting the column electrodes and thus display elements are formed at the intersections and the device comprises a control circuit for applying block-shaped data signals to the column electrodes and a line scanning circuit for periodically scanning the line electrodes and applying block-shaped line selection voltage signals, wherein during the frame time of the periodic scanning of the line electrodes, multiple lines n are simultaneously selected during a selection time, the line selection voltage signals to be supplied being different during the selection time for each of the simultaneously selectable lines, the amplitudes of the line selection voltage signals being equal for each of the lines to be selected simultaneously, and wherein the line selection voltage signals to be supplied of the lines to be selected simultaneously are mutually orthogonal, characterized in that the selection time (ta) for a group of a number of n lines is split into a number of selection time intervals which are distributed over the frame time such that the sum of these time intervals is equal to the selection time (ta) and such that during the scanning of the N lines no more than n lines 40 simultaneously wherein each of the lines to be selected simultaneously, the selection voltages to be applied during these time intervals are identical to the parts of the original line selection voltage signals of the relevant lines corresponding to the relevant time intervals. 2. A display device as claimed in Claim 1, characterized in that an odd number of lines is selected during a 45 selection time. 3. A display device as claimed in Claim 1, characterized in that an even number of lines is selected simultaneously during a selection time, one of the line selection voltage signals to be supplied being a unipolar voltage existing for a period equal to the selection time, and the other line selection voltages are signals of alternating polarity. 4. A display device as claimed in Claim 3, characterized in that the other line selection voltages of alternating polarity have the lowest possible frequency. 5. A display device as claimed in Claim 3 or 4, characterized in that the selection duration is divided into a number of time intervals of equal time duration such that the sum of these time intervals is equal to the selection time, wherein these time intervals are distributed over the frame time and scanning 55 of the N-line matrix no more than n lines are selected simultaneously, the line selection voltages to be applied to each of the lines to be selected simultaneously being identical during these time intervals to the corresponding parts of the original line selection voltage signals of the respective 194875 lines . 6. A display device as claimed in Claim 1, 3, 4 or 5, characterized in that 2, 4 and 8 lines are selected simultaneously. 7. A display device as claimed in Claim 1, 2, 5 or 6, characterized in that the selection duration is split into equal time intervals which are equally distributed over the frame time. 8. A display device as claimed in any one of the preceding Claims, characterized in that the amplitude Yn of the line selection voltages with simultaneous selection of n lines is given by Y '= N1 / 2 * XJn, wherein Xn is the maximum data voltage occurring in the data signals, and wherein Xn is given by Yn = n1 / 2 * V, * {0.5 / (1-N1'2)} 1'2 with Vn equal to the threshold voltage or the effective RMS voltage value of a display element in the "out "-status. A display device as claimed in any one of claims 1 to 7, characterized in that the number of lines N of the matrix is not a multiple of the number of simultaneously selectable lines n, an additional number of virtual, or 'dummy' lines n "Is assigned to the matrix such that the sum of N and nw is a multiple of n, and the amplitude Yn of the line selection voltages for simultaneous selection of n lines is given by Yn = N1 / z * Χ, / η, where X n is the maximum data voltage occurring in the data signals, and X n is given X '= n1 / 2 * V, * {0.5 (1-N'1 / 2)} 1/2 with V, equal to the threshold voltage or the effective RMS voltage value of a display element in the "off" state. Hereby 10 sheets of drawing