DE2141298C3 - Opto-electronic display device - Google Patents

Description

The invention relates to an opto-electronic display device with a display medium, which by means of a plurality of electrodes in individual Cells can be activated separately, the electrodes each with one of the electrodes belonging to the electrode Cell that can be illuminated and a cell that does not belong to the electrode.

luminous photoresistor are connected and the transparent, electrically highly conductive layers (2m. photoresistors cyclically one after the other with sliding 2n) are applied as second electrodes, and, furthermore, the use of it, outside the display medium (1), a such a display device for the time-electrically conductive layers (4m, 4n) larger measurement and the control of a display matrix. 5 resistor are applied, and on whose electronic display devices, for example, display medium (1) modified surface in the form of shift registers are of great importance for measuring and tric connection with the areas of the second control tasks of digital technology of great importance electrodes (2in, 2n) in accordingly separate action. If they are controlled by impulses through periodically repeating rich resistance layers (5 // 6m, 5m / 6n), they can also be worn for the io, which serve as electronic clocks when the time measurement is optically activated. Display medium, at least from the area of the after-The execution of such display sliding bar electrodes can be illuminated and, in the case of lighting registers or counters with self-illuminating display, reduce their electrical resistance , 4 ") greater resistance (USA.-Patent 2 999 165, German interpretation 15 of a common, also layered inscription 1 163 382, British patent 1 009 096), stepped busbar (II) - and the light-induced one not insignificant circuit-sensitive layers (S // 6m, Sm / 6 / i) in each case technical and energetic expenditure. In a known meter alternately applied in layers and in a known fully electronic line (A, B).

tronic clock (Electronics, July 6, 1970, p. 64 ff.) 20 A nematic

will therefore use liquid crystal segments as segments in order to save energy, the scattering activity of which

seven-segment indicator cells with liquid known to decay relatively quickly when the activating

crystal layers are used, which are switched off by applying voltage. But you can also

an electrical voltage are activated in this way, a mixture of a nematic and a

that they provide from the transparent to a light-scattering cholesteric liquid crystal. then

Override state. Since the control electronics here do not need constant lighting to be present

Energy for the light emission does not have to be, as is the case with the first-mentioned embodiment

■ _t \ the need for electrical energy is much lower. form is necessary, but it is sufficient to

:, These known counters or clocks also have men with a shift pulse on one of the control

; Disadvantages insofar as to control the correct 30 lines ignited lighting source, since the

Segments of the number to be displayed are known to be a complex scattering activity of the mixtures mentioned

■ I decoding is required, whereby the circuit decays almost indefinitely. To delete the

·. '$ Technical effort increases. Scattering activity of the last activated cell becomes this

^ From the German Auslegeschriften 1133 428. with a high-frequency pulse, for example some

! $ 1 197 123 and 1213 891 display devices 35 kHz are applied. There can be two control lines

vfj known, in which photoresistors are provided cyclically, which are in push-pull with shift pulse

" - ^: 'M are acted upon by shifting pulses applied to each other. In the case of nematic liquid

.yjjl Sleuer lines are laid. Such display device crystals, however, have a decay time compared to the

T, '§ lines need to excite light-emitting shift frequency too large, so be expedient

^ ■■; Ä the layers or gas discharge tubes additionally 40 provided several control lines, e.g. three at

: ^-:; ^ Hch energy sources of high voltage. At an intense 20Hz.

:, i '. ^ Ambient lighting is therefore readability.

; _; · ^? always difficult. moderately coherent liquid crystal

• ΐί '& ν The invention is based on the object of providing a display medium for counting cells

. '* & opto-electronic display device, in particular 45 formed, which are linked photoelectrically in such a way,

^ for time measurement or as a matrix display, so that with a simple activation via the control

il; create, which for the visual display only the diversions, the cells are updated practically error-free.

ambient light is required and its circuitry is switched and the number of control

% y and energy expenditure is therefore minimal. impulses or voltage change is displayed. the

S;> The above-mentioned task can be solved if the last counting status remains stored until

; ■? ' According to the invention, the display medium (1) is followed by a more fluid counting pulse. There is only one per display cell

is crystal, the photoresistors (Sa-6b, Sb-6c, only photoresistor required.

Sc-Sd ... Sxx-6xy, 5xy-6a) in parallel connection According to the embodiment described, this is

at least two cyclically with shift pulses electrode potential of a display cell strongly from

open control lines (A, B; A, B, C) laid 55 state of the liquid crystal display frame depending on

are each and for the purpose of forming a voltage divider, since this with the associated photoresistor

because it is in series with a preferably photoconductive, yes, a voltage divider. The electric one

the same light as the cells to be activated (1 a, but the resistance of a liquid crystal layer is over

Ib, Ic.) Exposed reference resistance (4) remained for a longer time with the materials known today

gene and a first transparent carrier plate (10) with 60 not constant. Therefore it is still necessary

a coherent, transparent, electrically in series with the photoresistors of a cell each

Well conductive layer (3) provided as the first electrode because a regeneration resistor is to be provided, which then

is that on one side of the display medium (1) with the photo resistors a voltage divider

comes, and on the other side of the display forms, the tap potential of which is largely independent

mediums (1) a second transparent carrier plate 65 is from the electrical resistance of the liquid crystal

(9) is arranged on which the display medium (1) is layered. The

facing surface in separate activating electrodes of a cell.

Areas in contact with the display medium (1) closed. The reference resistance is «n ™« · * «» »: -

a photoresistor exposed to the same light F i g. 9 shows the basic circuit diagram of an arrangement in

is like the cells to be activated. If this fluctuates which the shift register according to FIG. 1 for control

Light, e.g. B. the ambient light, in its strength, so tion of a display matrix is used,

If a cell is activated from the litter, the

light-illuminated photoresistors different 5 inventions in thin-film technology, in cross-section,

Have resistance values. With simultaneous and and

continuous illumination of the reference resistor Fig. 11 is a partially sectioned plan view

with the ambient light this can in a certain way be a component according to FIG. 9.

Dimensions are compensated. In Fig. 1, a display medium 1 is shown, the

The electrical energy required a display io between a continuous electrode 3 and vonvorrichtung according to the invention is also another separate Pre- electrodes la disposed to 2 d Providence of said reference resistance low,. As a result, cells 1 α to 1 d are formed which, because in the static state, are optically activated only in one span when a significant current flows between the divider, but the speaking electrode la to Id and 3 of a cell is only small , because for the activation of a display 15 an electrical voltage exceeding the threshold value for the onset of the light segments of a few mm ^{2 in} area is sufficient, about 10 uW. The electrical cell voltage is generated by the control

The display device can advantageously also be supplied as lines A or B. The resistances Sa

Integrated component in thin-film technology up to Sd and 6 a to 6 d are photoresistors,

will. 20 The control lines A, B are connected to an oscilloscope

To use the display 20 according to the invention, it is supplied with an alternating DC voltage device for measuring time or as a ring counter, as shown in FIG. 3 indicated. However, sixty or twelve electrode areas a sampled alternating voltage of about 50 Hz can be connected in front of a ring (in the geometrical or even just seen. When controlled with such an electrical sense) and the alternating voltage becomes the service life of the display to the voltage divider first cell of the ring medium elongated. The photoresistors 5 a to Sd hearing photoresistor of the last cell in such a way and 6 a to 6 d are arranged in such a way that they are unlighting, that it tet when optically activated and thus are high resistance, as long as none of this is illuminated. Thus, the display cells 1 α to 1 ti is optically activated.
device are operated in endless operation, where- 30 to start the switch 18 is actuated. About the seconds indicated by means of the sixty cells and the indicated in the device 17 and, as from minutes and by means of the twelve cells, the hours F i g. 2, essentially an AND element can be counted and displayed. Due to the fact that the circuit including an amplifier is tapping the voltage divider of the last cell of a then via the decoupling resistor 23 ring a flip-flop is controlled, the grain 35 activation voltage applied to cell la when the complementary outputs the control line of the voltage on line A goes to logic 1,
parent ring drive, are second, to make the switching process independently of any minutes and hours without their own frequency bounce phenomena of the switch 18 and divider counted and displayed. The number of contacting and leading to the outside to be able to determine the length of the start pulse is that in FIG. 1 only symbolically indicated switch connection points is small, about five connections are sufficient, expediently as shown in FIG. The switching closings per ring. Process is accordingly carried out by a mechanical,

Further details of the invention result from manually operated switching element initiated, which is

is formed from the switch or changer explained below with reference to the figures and how

th embodiments. 45 shows, on one of two NAND gates in TTL

F i g. 1 a schematic diagram of the technology according to the invention existing flip-flop acts. An exit

Display device, this flip-flop acts on a negative going

F i g. Figure 2 shows the embodiment of an edge-responsive dynamic input circuit

to start the display device, mono-flops. Since the flip-flop tilts when the

F i g. 3 has lifted the temporal sequence of shift pulses 50 moving switching element of the switch from rest to two control lines and the course of the scatter contact and on the other has fixed light intensities of two consecutive cells, contact, bouncing phenomena are eliminated, with the display being changed from one to the other. The time constant of the mono-flop is skipped over, chosen so that in the case of F i g. 4 is greater than T,

4 shows the timing of shift pulses 55 but smaller than 2Γ, and in the case of FIGS. 3 and 7

on three control lines, equal to or less than T. The mono-flop then gives

F i g. 5 shows an embodiment of the invention in the pulse S on the AND gate of the device

Thin-film technology as an integrated component, 17 and this the pulse St on the electrode la

FIG. 6 shows an embodiment of the invention as cell 1 a , the possible temporal positions of which are shown in FIG

Counting ring, in particular for time measurement, 60 are indicated. The fixed resistor 23 has the effect that

F i g. 7 the possible position and length of a start if the pulse St is already at zero, the ZeSe 1 a

impulses in relation to the control impulses but still has to be held from line A,

two risers, the voltage at electrode la does not collapse.

8 shows the pulse trains on two control lines, if in the embodiment in FIG. 1 a store if a store-acting mixture of emem 65 of the display dram, i.e. a mixture of emem nematic and a cholesterol liquid nematic and iron cholesterol liquid crystal is used, as well as the ignition times of the crystal, is used, the mono-flop 21 is with Illumination source, the light source 22 is provided. A flash of light off

ίο

This light source 22 then causes that from the beginning of the illumination of a resistor 6 by the shifting pulse on line A or B from the associated cell, the light determined by the tap 7 for the cells is above the threshold value on the photoresistor cell voltage, at levels 5 and 6 is scattered and this is low-resistance that the liquid crystal is light-scattering. Be accordingly. If, for example, cell la is ignited, cell Ic remains in the light-scattering state, then the voltage on line B via 5a means that the maximum voltage on line A is long. The cell Ib activated. On line A , a photoresistor 6c or more generally the photo high-frequency pulse of about 1 kHz is generated, which the resistors 6 thus serve to extinguish the light-scattering scattering activity of the cell 1 α again. This is to be kept in state or the respective counter state F i g. 8 shown. Store the source for the high frequency io.

impulse is not specifically shown and in the oscillator The photoresistors 5 are used for switching 20 to think incorporated. When voltage B falls again to the optical activation of one cell and voltage A rises again, it becomes next again. In Fig. 1 photoresist is generated, for example, a suitable flash of light, which now photo- c 5 from the cell 1 c forth illuminated and Sb low resistance low impedance and is activated cell Ic 15 is resistive. Characterized reaches the electrode 2a 'is four. The spreading activity of the cell 1 b cell 1 is then d at the instant a voltage which connected the overall by a high frequency pulse on line B voltage on line B to maximum extinguished. The high-frequency pulses can The two lines work in push-pull, being square-wave alternating voltages whose or cyclic alternating voltages are in relation to one another.The transition in the control amplitude is, for example, three times greater than that of the shift voltage from line A to line B is shown in FIG 3 impulses on lines A or B. The high-frequency shown. As can be seen, the time of the impulse occurs after a certain delay in switching off the voltage A compared to the start of a shift pulse, so that the transfer point r, the switching on of the Voltage B can be carried out safely by the time from one cell to the other, span r delayed. This ensures that the length of the light flash 22 is given by the a s the photoresistor 5c only becomes high-resistance again. Duration of the transfer from one cell to the other when the transfer to cell 1d has definitely taken place plus the erasure duration, since the erasure has taken place via Photo-. After switching off the voltage A falls resistance takes place. After the intensity of the light scattered by cell 1c has been extinguished as previously activated, all three signals can be shown from the value / ₀ to zero. At the same time 22, A, B according to put 8 to zero Fig., Since 30 increases the intensity of the pe.streuten of cell Id Lichdie storage tes ensured in the display layer after a delay to a value above and given anytime a new shift pulse / ₀ on, since the photoresistors 5c and 6d can initially be. If a nematic liquid crystal is provided at 7 a "high. Only when the light intensity is high must constant illumination of the cells in front of the point in time i _ä be anticipated, since that scattering power is sounded by each resistor 5 and c again high impedance liquid crystal layer thickness in z. B. 1 second is arises d falls back to the switching off of the voltage activating the intensity of the cell 1. in a value I _0.

Fi g. 1, in addition to the photoresistors 5 a to 5 c, the resistors 4 a to 4 d are to be provided so that the cell to be activated can develop a voltage ranging from 6 a to 6 a ″ and also serial reference fixed resistors 40 For the passage of current in a cell, photoresistors 5a / 6b, Sb / 6c, Sc / 6d are expediently integrated in one piece over two cells compared to that of the associated, illuminated photo That is the case in the unilluminated one according to Fig. 5. In the illustrated off state with maximum voltage on the associated guide, it is assumed that a constantly active control line is provided for the potential of the tap not the light source, such that only the photo threshold for the onset of scattering in the resistors are illuminated, which exceeds an optically liquid crystal.

activated Ze-Ie are assigned (e.g. 6c and 5c if the time Τ-τ (Fig. 3) between two at cell Ic). The fixed resistors 4a to 4d are 50 control pulses on the same line is too small, at one end to ground, so that a span from the resistors than that the last activated cell is sufficiently spaced 5/6 and 4 for each cell 1 α to 1 d - Could sound, can be created by controlling more voltage dividers, the potential of which in tap la, as two lines, can be made practically arbitrarily large Ib, Tc and Id by the lighting of the photoresist this time. The is for three lines in Fig. 4 probe 5/6 depends. The resistors 4 are used for 55 shown: The voltage divider of a cell controlled with the first pulse on line A better definition of the voltage divider ratio, therefore the resistance of the display cell is only controlled again when it can be checked. The cells 1 α to 1 d are controlled with the tap potentials on the two other lines B and C each with a pulse. In Fig. 2 has passed through the cell remains an indication that the reference resistors 4a, 46 ... 60 ringing time 2T - x.

can also be photoresistors, from which the In F i g. 1 there is still an optical potentiometer 24, advantages explained above. indicated. This can consist of two resistance tracks. To explain the function of the display device (metal layers) it is assumed that the cell 1 c is connected to an optically activated photoconductor beam. The two fourth, respectively, is stimulated. Then the control line A 65 Resistance tracks are only constant at maximum voltage, so that the voltage current / fed and at the location of a lighting, z. B. teSer 5f> / 6c, 4c a current flows The resistors at cell Ic in Fig. 1, via the conductive voltage divider there, are dimensioned so that the photoconductor is electrically connected. It can then be a

11 12

Position reporting voltage U are tapped, which are located in them on both sides of the masks

In an analogue form, the digital display of the front-transparent columns 14 /, 14m, 14 ”is illuminated

indicating direction according to the invention. That optical can be.

Potentiometer can also be used as a silicon bar with The liquid crystal layer 1 can also be between

a metal film. 5 parallel polarizers are set if the same

The display effect can also be prepared by means of color control in such a way that the electrodes, in combination with suitable color filters, show the Schadt-Helfrich effect. The nematic host liquid crystal, pleochroic lower nematic host liquid crystal, is necessary if, in a known manner, the agile activation voltages are lower.
Color molecules are added as a guest. io Of course, the masks 8 are not in

In Fig. 5 shows how an arrangement is drawn in after the display area D. FIG. To avoid fig. 1 in thin-film technology, as a layer structure, an exposure of the photoresistors from can be produced. The component shown is display part D ago, the vertical separation can also be thought of as a longer element cut out in the area of the cell surface in plate 9 between area K and D from 1 / to 1 η . The glass plate 15 is darkened.

th 9 and 10 are positioned by spacer strips 12 so that the shift register can also be used as an indication that a liquid crystal layer 1 is used by time measurement. For this purpose, the most constant thickness possible, e.g. B. 25 μ arises. In the order of FIG. 2 expanded to sixty segments of the glass plate 10, a continuous, transparent tin dioxide is carried out between the spacer strips and the coupling with the neighboring elements so that a closed ring is formed. Electrode 3 applied. On the side of the glass plate 9 directed against the liquid ring, the geometrical figure crystal layer 1 need not be understood. Of course, it is also sufficient to first use black mask strips 8 /, 8 m, 8/1 if the first and the last segment are electrically connected and then separated, transparent ones are coupled and thus a ring only in the electrical SnO., Strip electrodes 2 /, 2m, In ... created, the- astric sense arises. The resulting arrangement, that only the one not of the black bars in, is shown in FIG. 6 shown. Is α, the first cell 1 with Fig. 5 overlapped gaps 14 / 14m, 14η each of the last cell 60 'of the ring over the photo Approximately in the middle of the electrodes 21, 2m, into resistance ... Sxy / coupled 6a so that If the line A is activated, the electrode la of the cell la remain

The electrodes 2 /, 2m, 2η on the one hand receive the necessary activation potential from the tap Ta to the end of the glass plate 9 up to the photoresistor, since the partial resistance Sxy of the photoresistors 5 / 6m, 5m / 6n, on the other hand up to the fixed stand 5xyJ6a because of the lighting from the cell resistors 4 /, 4 m, 4 η and is electrically low with these 60 "ago. The electrode of the penultimate tric connected. The resistors 4 /, 4m, 4 η are Cell 59 ″ is marked with 2xx, that of the last cell 60 ″ with the one on the other side with a highly conductive 35 ″ 2xy. Correspondingly, the fixed resistor is connected to the SnOy rail 11, which is preferably grounded, of the voltage divider belonging to the last cell 60 ″. labeled 4xy .

The control lines A and Γ are also called The control lines A, B are shown in

SnOo-Schichlen executed, with an electrical case switched at a frequency of 0.5 Hz, so that

Isolation of the crossing points by local insulation 40 a pulse duration and thus an activation

latorschichten 13 is achieved. As can be seen, the duration of T = 1 second results

thus electrically the in F i g. 1 shown execution for the start of the counting or timing device

production shape. becomes, as shown in FIG. 1 described, about the device

The embodiment shown in FIG. 5 is supplied with a start pulse Si in device 7. After 59 seconds

three areas K, D and F (coupling, display and 45 den intervals, the activation of seg-

Fixed resistors). The underside is transmission 59 "on segment 60". This creates on the

parent for the light from a light source L, the overhead line 19 is a pulse whose amplitude is the

side is darkened in area K, transparent in the threshold value for the activation of the liquid crystal

Significantly exceeds area D and transparent or darkened. In this case,

rich F. 5 ° equipped with a corresponding threshold

The device can in transmission, but also th Schmitt trigger 15 emitted a pulse that the

operated in reflection. In reflection mode toggle flip-flop 16, which is a flip-flop with a

the electrode 3 is mirrored in area D , so that dynamic input acting on both fields,

for the observer O the falling from above overturns. The complementary outputs A * and B *

ambient light scattered by the activated cell 55 of the flip-flop 16 can then be used to operate the

will. For the optical coupling between scattering control lines of a second display ring counter, the

Cell and photoresistors are located in area K of nen, which counts the minutes and at the same time counts

below shows light from the light source L above the package.

mator 7, e.g. B. a fiber optic front panel, fed In the same way, another ring with twelve

The collimator 7, together with the masks 8 /, 8 m, 60 segments are formed, which enumerates the hours

Sn, has the effect that when the display is not activated, the corresponding

Leaves little light on the photo resistors 5116 m, electrodes are shaped in such a way that digits 1 to 12 S m / 6 η only appear when in the area, for example, the elec- trodes are activated and displayed one after the other. When

If 2 m light scatter occurs, at least one functionally necessary continuous or reperitive Part of the scattered light through gap 14 m on which 65 pulsed lighting is not guaranteed

Photoresistors drop 6 m and 5 m. For this purpose, the time pulses are additionally used in a counting device, the photoresistors 5 // 6 m, S m / 6 η of the conventional type are enumerated and thus arranged approximately in the middle above the masks 8, so that displays are re-created at the appropriate point

initialized. For this purpose, the Counting rings are interrupted at suitable points and controlled from the outside at the right time.

In Fig. 9 nor the control of a display matrix PC / LC by means of a shift register of FIG. 1 is finally depicted The display matrix LC comprises liquid crystal cells, which can be controlled via photoresists PC from a line V forth, as they pass exposure low-

are ohmic. If the shift register is switched on in the manner according to the invention by means of alternating voltage on the control lines A, B , one photoresistor after the other is correspondingly continuously made low. This allows x ₅ voltage value corresponding to the line V Lieh display value of the corresponding matrix cell of each chip. The matrix display can be operated by means of digital voltage values on the line K. With enough linear photoresistors PC , video signals can also be displayed. The described use of the shift register solves the technically important task of "self-scanning".

In Fig. 10 a further embodiment of the display device is shown as an integrated component in thin> ₅ layer technology in cross section, and in F, g ^ 1 in a partially sectioned plan view. The partial electrodes of the electrode 26 are connected to the taps · _{s nungste} jl _e ni, the schichtvu »f ^ include ₁₁₆₀ Photo resistors 5, 6 and the fixed resistor rhichlförmigen. 4 The sum .. ^^^ _sin d with control lines Λ, B, di _e £ "" .. _{would be} connected to a ground line, resi ^^ ^ are plotted in a hight shape. Except for u photoconductor track 24 provided which, like

ate ... _the p _os itionsmeldespannung U ER-

above Descnn,

^χχ ψ \. _two white, diffusely reflecting plates, preferably elongated light

^ten , f ^J '^ _dnet . I _n of the carrier plate 28 to ^que "" f _{dt plate} 33 _s i _n d square openings 37 S ^ anu _t ^^ _{DJE display layer,}

^ ™ _{bere Τΐ88} βφΐ8 «β 29 can fall until ^ n ^d * ^ ⁸ ^ covered _by opaque, ü« α β ₃ ^ ^ ^ _{{) that da &}

black _{space only fa dem d me}

Light «» «. _{w to the upper mask} 35 _ge ,

ne en D ⁰ PP ^ f _e ^e _durchst ^ _ahlte display layer trans can be so attached Uie ü ^

parent is. be, ^ ^ ^^ ^^^ _e _ _ner ^^

ap _ for example the cell Ib licht so scattered light arrives according to the Pfeiso geia gg ^^^ _{das Ljcht} ^ ^

_{5 6 reflects> the otherwise unconcerned} . _{No dur <; h the Ve}

, while ^

(Fig. 11). Electrode27 is grounded, while the 35 can, which cell in each case

, flj, _dm observer O and is.

In addition 7 sheets of drawings

Claims (26)

Patent claims: 1. Opto-electronic display device with a display medium which can be activated separately by means of a plurality of electrodes in individual cells, the electrodes each being illuminable with one cell belonging to the electrode and one illuminable by a cell not belonging to the electrode Photoviderstand are connected and the photoresistors are cyclically applied one after the other with shifting pulses, characterized in that the display medium (1) is a liquid crystal! is, the photoresistors (Sa-6b, 5b-6c, 5c-6d ... 5xx- 6 xy, Sxy-6a) are connected to at least two control lines (A, B; A, B, C) that are subjected to strokes and for the purpose of Formation of a voltage divider in series with a preferably photoconductive, the same light as the cells to be activated (la, Ib, Ic ...) exposed reference resistor (4) and a first transparent carrier plate (10) with a coherent, transparent , electrically good »5 conductive layer (3) is provided as the first electrode. which comes to lie on one side of the display medium (1), and on the other side of the display medium (1) a second transparent carrier plate (9) is arranged, on whose surface facing the display medium (1) in separate areas in contact with the display medium (1) transparent, electrically conductive layers (2m, 2 / i) as second electrodes and, in electrical connection therewith, outside the display medium (1) electrically conductive layers (4 m, 4 / j) larger resistance are applied and on the surface facing away from the display medium (1) in electrical connection with the areas of the second electrodes (Im, In) in correspondingly separated areas resistance layers (51/6 / w, 5 «ι / 6 μ) are applied, which can be illuminated at least from the area of the neighboring electrode when the display medium is optically activated and, when illuminated, reduce their electrical resistance, the layers (4 m, 4n) having greater resistance at a ge common busbar (11) also applied in layers and the light-sensitive layers (51 / 6m, Smj6n) in each case alternately on control lines (A, B) applied in layers. 2. Display device according to claim 1, characterized in that the display medium is a nematic liquid crystal. 3. Display device according to claim 1, characterized in that the display medium a mixture of a nematic and a cholesteric liquid crystal is that one together lighting source ignited with a shift pulse on one of the control lines for the display medium is provided and that the last activated cell after completion of the Activation is applied with a high-frequency pulse for the purpose of deleting the scattering activity. 4. Display device according to one of claims 1 to 3, characterized in that two control lines (A, B) are provided, which are alternately applied with a Stcuer DC voltage. 5. Display device according to claim 1 or 2, characterized in that the number of control lines (A, B, C) is so large that b · ^: m applying a control line (z. B. B) with maximum voltage, the optical scattering activity of the last driven by this control line cell (eg. B 1 b) has decayed sufficiently strong that the (b 1) illuminated photoresist (6b) is generated from this cell, an electrode potential of the cell is below the threshold for optical activation. 6. Display device according to claim 5, characterized in that three control lines (A, B, C) are provided. 7. Display device according to one of claims 1 to 6, characterized in that the Shift pulses are packets of low-frequency alternating voltage. 8. Display device according to one of claims 1 to 7, characterized in that the Photoresistors (5, 6) are integrally formed. 9. Display device according to one of claims 1 to 8, characterized in that in Series with the photoresistors (5, 6) each have a reference resistor (4) for the purpose of forming a Voltage divider, to whose tap (7) the associated electrode (2) is then connected. 10. Display device according to claim 9, characterized in that the reference resistor (4) of the voltage divider of a cell (Ia, 1 b ... 59 ", 60") is a photoresistor which is exposed to the same light as the cells to be activated (la , \ b, Ic ...). 11. Display device according to claim 9 or 10, characterized in that the resistance value of a voltage divider (eg 4 c, Sb / 6 c) in the illuminated state is small compared to the resistance value of an activated cell (eg 1 c). 12. Display device according to claim 9 or 10, characterized in that the potential difference between the electrodes ( e.g. Ib, 3) of a cell (e.g. 1b) for the resistance value of the associated voltage divider (e.g. Ab, 5a / 6fe ) in the unlit state and at maximum voltage on the control line connected to these electrodes (e.g. ß) is less than the threshold value for the optical activation of the display medium (1). 13. Display device according to claim 9 or 10, characterized in that the potential difference between the electrodes (e.g. 2 c, 3) of a cell (e.g. 1 c) for the resistance value of the associated voltage divider (4 c, Sb / 6 c) when illuminated and at maximum voltage on the control line connected to it (e.g. A) is greater than the threshold value for the optical activation of the display medium (1) 14. Display device according to claim 2, characterized in that in the liquid crystal pleochroic color molecules are stored as a host as a gas. 15. Display device according to one of claims 1 to 14, characterized in that dai 2 14? 298 an optical potentiometer (24) that can be illuminated by the cells (la, Ib, Ic ...) is provided, in which two electrical resistance tracks are electrically connected at the location of the lighting, the electrical resistance of the tracks from the end to the location of the lighting for Deriving a position signaling voltage (U) is used. 16. Display device according to claim 9 or IO in thin-film technology, characterized in that a first transparent carrier plate (10) is provided with a coherent, transparent, electrically conductive layer (3) as a first electrode which is applied to one side of the display medium (1 ) comes to rest, and on the other side of the display medium (1) a second transparent carrier plate (9) is arranged, on whose surface facing the display medium (1) in separate areas in contact with the display medium (1) ao transparent, electrically highly conductive layers (2m, In) as second electrodes and, in electrical connection therewith, outside the display medium (1) electrically conductive layers (4m, 4n) of greater resistance are applied and on their surface facing away from the display medium (1) in electrical connection with the areas of the second electrodes (2m, 2 m) in correspondingly separated areas on resistance layers (S // 6m, 5m / 6 n) are worn, which can be illuminated at least from the area of the neighboring electrode when the display medium is optically activated and which reduce their electrical resistance when illuminated, with the layers (4m, An) of greater resistance lying on a common busbar (11) which is also applied in the shape of a shaft and the light-sensitive layers (S 1/6 m, 5m / 6/1) each alternately on control lines (A, B) applied in layers. 17. The display device according to claim 16, characterized in that (m 4, 4 ') and layers greater resistance photoresistors are provided which are exposed to the same light as d \ £ cells to be activated (la, Ib, Ic ...) 18. Display device according to claim 16 or 17, characterized in that the light-sensitive resistance layers (SI / 6m, S m / 6 ") can be illuminated from two adjacent electrode areas (2 // 2m, ImIIn). 19. Display device according to claim 18, characterized in that on the side of the first carrier plate (10) facing away from the display medium (1) an arrangement collimating the incident light is attached and the areas of the second electrodes (21, 2m, 2 ") are opaque Masks (8 /, 8 m, 8 ") are covered in such a way that a transparent gap (14 /, 14m, 14") remains open only in the middle of an electrode area (21, 2m, 2 / i). 20. Display device according to claim 9 or 10, characterized in that it is designed as an integrated component using thin-film technology, such that the display medium (1) is arranged between transparent electrodes (26, 27) applied to carrier plates (28, 29), and the carrier plates (28, 29) are covered with opaque masks (30, 31, 35) in such a way that there; Display medium (1) at least partially for da; Ambient light (E) and the observer (O) is exposed, and a darkened room (36) comprising at least the photoresistors (S, 6, possibly 4, possibly 24) is created, which only occurs when a cell is activated (... Ib .. .) of the display medium (1) and only in its area is illuminated by means of light (F) scattered by the cell (... Ib ...). 21. Display device according to claim 20, characterized in that all photoresistors (5, 6, optionally 4, optionally 24) are arranged on a carrier plate (28) in a plane with the transparent, subdivided electrodes (26) and a mirror (32) is provided, with which the light (F) scattered by an activated cell is directed to the photoresistors. 22. Use of a display device according to claims 1 to 21 for time measurement, characterized in that sixty or twelve electrode areas (2a, 2b ... 2xx, Ixy) are combined to form a ring, and the voltage divider (4a, SxylSa ) Photoresistor.d (Sxy) belonging to the first cell (Ia) of the ring is assigned to the last cell (60 ") in such a way that tr is illuminated by the latter when it is optically activated. 23. Use according to claim 22, characterized in that a flip-flop (16) is controlled from the tap (Ixy) of the voltage divider of the last cell (60 ") of the ring, the complementary outputs (Q, ~ Q ~) of which the control lines ( A *, B *) control another counter ring. 24. Use according to claim 22, characterized in that the electrode areas (2a, 2b ...) are shaped like digits. 25. Use according to claim 22, characterized in that parallel to the display device according to claim 1, a light-independent counter is operated from which at one If the lighting is interrupted, the display device is reinitialized in the correct place can be. 26. Use of a display device according to one of claims 1 to 21 for controlling a display matrix, the display elements (LC) of the matrix being connected to the control line (V) for the signal to be displayed via their own photoresistors (PC) , which in turn are each connected to the individual Cells (la, Ib, Ic ...) of the shift register are optically assigned.