DE4042388C2 - - Google Patents

Description

The invention relates to a display device according to the preamble of claim 1 or claim 2.

Such a display device is known (US 22 22 937, in particular embodiment according to FIG. 5). At this known display device is the collimator Lens or lens system formed. It will be a slim one Beams generated by means of a modulation device modulated in terms of its light intensity and finally in an image plane of a positive lens system. The bundle of rays is by means of an optical deflector, the designed as a polygon prism of a certain construction is, for the purpose of line switching from line to Line distracted. A second deflector is also provided, which deflects the light or image point horizontally  and thereby leads along an image line. To this The pixel is wise line by line over the entire Recorded area, so that there is a two-dimensional Picture arises.

This known display device needs in the Image plane a recording or reproduction area at least in the size of the two-dimensional to be reproduced Picture. It also needs two polygon prisms with mutually perpendicular central axes, whereby each of these polygon prisms is at least the length of the Image in its horizontal direction or in its vertical direction must have. The known display device therefore has a relatively large space requirement.

The invention has for its object the generic Display device according to the preamble of claim 1 and according to the preamble of claim 2 to further educate them as far as possible is compact.

This object is achieved by the display device solved according to claims 1 and 2. The only difference between these two solutions is: the formation of the optical deflector in one case as Polygon prism and in the other case as a reflective one Mirror; otherwise they agree with regard to training and its advantages explained in more detail below match.

In the display device according to the invention, the Modulation device a liquid crystal shutter arrangement, which is the incident beam of rays for a full picture line modulated. So that without distortion can be done is the liquid crystal shutter arrangement arranged in a bundle of parallel rays of light,  that of the one specially trained for this purpose Collimator is delivered. So that the liquid crystal Closure arrangement can have sufficient dimensions, has the beam in the area of liquid crystal Closure arrangement a comparatively large bundle cross-section, behind the liquid crystal shutter assembly is narrowed by means of the converging lens arrangement, so that for the liquid crystal shutter assembly for Comparatively large bundle cross-section provided not a correspondingly large polygon prism or a correspondingly large reflecting mirror required. The center or rotation axis of the (single) deflector the display device according to the invention runs towards a picture line and thus towards the larger size of the liquid crystal shutter assembly. Because the latter beams of rays falling on them modulated over the entire length of a picture line, it comes display device according to the invention without the second deflector from that in the known display device for the scanning along an image line provides. One and only Deflector of the display device according to the invention provides for line switching. In cooperation with the The eyepiece causes the deflector to be all rays despite varying degrees of distraction run a predetermined point, which results in that at this point the device axis with different Cut the slope so that an observer can Has the impression that the individual image lines on in the vertical direction to see different positions so that with successive playback of the individual image lines the impression of a two-dimensional image is created. However, it is not a playback or recording area present in the image planes in the vertical direction and horizontal direction at least the dimensions of the displayed image. The display device according to the invention both according to claim 1 and  according to claim 2 can thus be much more compact be formed as the known display device.

Embodiments of the invention are in the drawings shown and are explained in more detail below. It shows

Fig. 1 is a schematic side view of a first embodiment of the invention,

FIG. 2 is a partial sectional view of an optical liquid crystal shutter row of the display device according to FIG. 1,

Fig. 3 is a partially broken perspective view of the liquid crystal optical shutter array shown in Fig. 2,

Fig. 4 is a diagram for explaining the control of the liquid crystal optical shutter array shown in FIGS. 2 and 3,

Fig. 5 is a fragmentary perspective view of a modified liquid crystal shutter row,

Fig. 6 is a schematic side view of a second embodiment of the display device,

Fig. 7 is a perspective, schematic view of an example of a first embodiment in the applicable deflector and

Fig. 8 shows a further example of a deflector.

Fig. 1 shows a display device according to a first embodiment.

The display device according to this embodiment has a color image display unit or display unit 627 (hereinafter referred to simply as "display unit") for a horizontal image or scan line, an optical deflector 628 and a positive lens system in the form of an eyepiece 629 . The optical deflector 628 has a polygon prism 611 in the form of a regular four-sided prism. A driver circuit 630 controls the driving of the polygon prism 611 at a predetermined speed.

The display unit 627 has a light source 631 , a reflecting mirror 653 , optical liquid crystal shutter rows 632 R, 632 G, 632 B, which form a liquid crystal shutter arrangement 632 , and a converging lens arrangement 633 . Each optical liquid crystal shutter row 632 R, 632 G, 632 B is connected to a driver 634 R, 634 G, 634 B for the corresponding optical liquid crystal shutter row. The converging lens arrangement 633 is formed by combining two cylindrical lenses 635, 636 . The liquid crystal shutter arrangement 632 and the converging lens arrangement 633 together form a modulation device which modulates the light emitted by the light source 631 as a function of control signals.

Fig. 2 shows a partial sectional view of the optical liquid crystal shutter series 632 R or 632 B or 632 G used in this embodiment, while Fig. 3 shows a three-dimensional representation thereof.

As shown in Fig. 2, a liquid crystal 639 is sandwiched between glass plates 637 and 638 . The liquid crystal 639 is a ferroelectric liquid crystal with two bistable states, that is, in this liquid crystal, molecules of the liquid crystal are polarized arbitrarily by electrical means and within a short period of time corresponding to the positive and negative charges of an external electric field, a transition between the two subject to bistable states.

A common electrode 640 is arranged on the glass plate 637 , while individual electrodes 641 are provided on the glass plate 638 . Both the common electrode 640 and the individual electrodes 641 represent transparent electrodes which are formed from ITO or a similar substance. The common electrode 640 is integrally arranged in the longitudinal direction (as shown in the drawing in the horizontal direction) of the optical liquid crystal shutter row 632 R. The individual electrodes 641 are lined up in the same direction and separated from one another by a predetermined number (this number corresponds to the number of picture elements).

A polarizing plate 642 is arranged on the upper surface of the glass plate 637 via the common electrode 640 , while a polarizing plate 643 is arranged on the lower surface of the glass plate 638 . These polarizing plates 642, 643 are set or adjusted so that their polarization planes are each shielded from one of the bistable states by the light beam. That is, the light beam is not transmitted through the liquid crystal 639 if the liquid crystal 639 is in a first of its bistable states, while the light beam is transmitted through the liquid crystal if the liquid crystal is in the other state of its bistable states.

The 632 R optical liquid crystal shutter array has a structure and an arrangement such as that disclosed in Japanese Patent Application Laid-Open No. 5,326 / 1988.

According to this embodiment, a filter 644 is provided on the lower surface of the glass plate 637 . Each filter 644 is able to allow the light beam of one of the three main color components red, green and blue to pass through. As described above, according to the described embodiment, three rows of optical liquid crystal shutters 632 R, 632 B and 632 G are provided, which means that the three rows of optical liquid crystal shutters are each equipped with filters 644 , each of which is the light beam of a color component red (R), green (G) and blue (B) allow passage.

Fig. 3 shows such an arrangement in perspective.

In this drawing, the liquid crystal 639 is omitted for the convenience of explanation. As can clearly be seen from this illustration, the optical liquid crystal shutter row 632 R or 632 B or 632 G is also arranged such that the common electrode 640 lies on the side facing the light source 631 .

As can also be seen from the illustration, a driver section 645 is provided for each individual electrode 641 . The driver section 645 is formed by a thin-film transistor, the circuit arrangement of which is shown in FIG. 4.

In FIG. 4, the driving section 645 647 648 corresponds to in each case one individual electrode 641, and has thin-film transistors 646, at whose number corresponds to the number of picture elements. Thin film transistor 646 functions as a load resistor for thin film transistor 647 . A supply voltage V _DD is applied to thin film transistor 647 via thin film transistor 646 which is connected to a drain. A connecting line to the single electrode 641 is taken from the drain of the thin film transistor 647 , and the source of the thin film transistor 647 is grounded with half the voltage V _DD applied to the single electrode 641 .

The source of thin film transistor 648 is connected to the gate of thin film transistor 647 . The gates of thin film transistors 648 are shorted in units of a predetermined number of gates. This short-circuited unit is referred to below as a block.

A scan circuit 649 is connected to the gate of thin film transistor 648 . Furthermore, a signal supply circuit 650 is connected to the drain connection of the thin film transistor 648 . The scanning circuit 649 and the signal supply circuit 650 form a driver device 634 R or 634 B or 634 G for the optical liquid crystal shutter arrangement.

According to this embodiment, the signals applied to the drain terminals of the corresponding thin film transistors 648 represent video signals for the respective picture elements. Thus, when the video supply circuit 650 sends a video signal to the drain terminal of the thin film transistor 648 with the thin film transistor turned on 648 is given, this video signal is supplied to the liquid crystal 639 through the thin film transistor 647 . The liquid crystal 639 then takes one of the bistable states. In other words, the light corresponding to the video signal is transmitted through each picture element of the optical liquid crystal shutter device 632 .

A signal to turn the thin film transistor 648 on or off or to turn it on or off is a block select signal which is input from the sensing circuit 649 to the gate of the thin film transistor 648 . As described above, since the liquid crystal 639 is a ferroelectric liquid crystal which has a relatively short transition time between the bistable states, this transition time is of the order of magnitude comparable to a horizontal cycle (about 63.5 µm sec) of the NTSC system is comparable. Accordingly, it is advantageous to drive or actuate for each block, ie block by block, in order to create free time for driving, displaying and deleting the optical liquid crystal shutter arrangement 632 . Accordingly, in this embodiment, switching from passing to shielding the light beam is carried out for each block.

Specifically, the video signal of thin film transistor 648 is held until a block select signal is supplied, and switching between passing and shielding the light beam is accomplished in block units in accordance with the arrival of the block select signal. The block select signal is sequentially applied to all blocks and all blocks are driven in one horizontal cycle.

As a result, when viewed in units of blocks, the display time is extended so that a high contrast ratio is provided. Furthermore, the response when switching thin film transistor 648 can be moderate.

The overall operation of this embodiment will be described in more detail below.

First, a light beam is emitted from the light source 631 , which after conversion into parallel light beams with the aid of the reflecting mirror 653 is incident on the corresponding optical liquid crystal shutter rows 632 R, 632 G, 632 B.

The optical liquid crystal shutter rows 632 R, 632 G, 632 B are - as described above - driven by corresponding driver devices 634 R, 634 G, 634 B for the optical liquid crystal shutter rows, with the result that light beams of the three colors R, G and B can escape or be shielded.

These light rays fall on the converging lens arrangement 633 . The converging lens array 633 causes the light rays incident thereon at the same intervals as the array intervals of the optical liquid crystal shutter rows 632 R, 632 G, 632 B to converge near a predetermined axis.

The bundled or converged bundle of parallel light beams is directed onto the polygon prism 611 . The polygon prism 611 causes light to emerge from it, performing a repeated scan. In the present case, since the light of each color has converged parallel to the axis through the converging lens arrangement 633 , it can be assumed that a reversal or repetition occurs simultaneously for each color during the scanning.

The beam of rays emerging from the polygon prism 611 is directed so that it is incident on the eyepiece 629 . The eyepiece 629 is a positive lens system that has a predetermined focus. It should now be assumed that there is a viewpoint in this focus. The light beam incident on the eyepiece 629 along an optical path indicated by the solid line in FIG. 1 is seen as if it had arrived from a direction indicated by dashed lines. While the polygon prism 611 is driven under the control of the associated driver circuit 630 , the polygon prism 611 is repeatedly scanned and the viewer visually feels an image screen of a size determined by the configuration of the polygon prism 611 .

It should be emphasized that the eyepiece 629 can be designed according to the size of the visually perceived imaging screen. The rotation cycle of the polygon prism 611 must be determined in accordance with the vertical scan cycle of the video signal.

Accordingly, according to this embodiment, it is sufficient to provide a display unit 627 corresponding to the picture elements for a horizontal picture line, so that the display unit can be made compact and can be produced with high production yield at low cost.

It is also possible to improve the resolution by providing a sufficiently high high-speed rotary motion of the polygon prism 611 . Consequently, the display unit is suitable for use as an image finder of a camera. This is explained in more detail below.

The size of a picture element in a conventional one Color liquid crystal display device with a two-dimensional Display is generally some 1 / 100th of a millimeter times some 1 / 100th of a mm. If, for example, a display with a diagonal dimension of about 20 mm for one Image viewer of a television camera through a color Liquid crystal should be realized, so exist Limits on the number of horizontal picture elements and the number of vertical picture elements in the area from 300 to 400 or from about 250. In addition  is the number of horizontal picture elements per Color approximately between 100 and 130, this number being one Third of the total number of horizontal picture elements matters. For this reason, such a display device able to realize a resolution that is much less than the resolution of one Imaging device of a television camera. Since further the number of picture elements is much smaller than the number of effective (vertical) scan lines, which is 500 for the NTSC method, one is sufficient Display device not for a focusing operation a television camera.

The described display device using the liquid crystal optical shutter assemblies is capable of vertical resolution due to the rotational speed of the polygon Prism and the display switching speed of the optical liquid crystal shutter assemblies on a to raise high level.  

Fig. 5 explains a modification of the first embodiment. In this drawing, for the sake of simplicity, only the arrangement in the vicinity of a common electrode 740 is shown. Reference numerals increased by "100" designate elements corresponding to the first embodiment.

According to this modification, filters 744 are provided, which are in separate form for each picture element. According to this arrangement, if the adjacent filters 744 are formed by filters which allow light of different colors to be transmitted, it is possible to handle a variety of colors with the aid of an optical liquid crystal shutter line. As a result, the arrangement and structure of the display unit can be kept compact and the display units can be manufactured at a low cost.

It should be noted that the filters 744 , which are arranged in an optical liquid crystal shutter row in an adjacent position relationship to one another, are preferably red or blue filters which have a relatively small influence on the resolution.

Fig. 6 illustrates a display device according to a second embodiment. Reference numerals increased by "300" designate elements corresponding to the first embodiment.

According to the second embodiment, the rows of optical liquid crystal shutters are combined in terms of the colors red and blue to form a single row of optical liquid crystal shutters 932 RB. A corresponding driver circuit 934 RB is also provided for this optical liquid crystal shutter series.

The special feature of this embodiment is that an optical deflector 928 is designed as a movable mirror 951 , to which a driver circuit 952 is assigned.

Specifically , a beam of rays coming from a converging lens arrangement 933 is deflected by the oscillating movement of the movable mirror 951 and directed onto an eyepiece 929 . The driver circuit 952 causes the movable mirror 951 to swing with a swing cycle corresponding to the vertical scan cycle.

Accordingly, it is also possible with this embodiment to obtain a compact display unit in the same way as with the first embodiment. It should be emphasized that it is sufficient to place the movable mirror 951 on a galvanometer (not shown), and the length of the mirror can be determined according to the length of the optical liquid crystal shutter assembly 932 .

It is possible to use a monochromatic display unit to use.  

Exemplary embodiments for the optical deflector 638 of the first embodiment are explained below.

In the exemplary embodiment according to FIG. 7, the optical deflector has a polygon prism 11 which is formed by a regular four-sided prism. The polygon prism 11 is clamped with its opposite end faces between a pair of holding members 12, 13 . The holding element 12 is connected to a rotating shaft 14 which is rotatably supported by a bearing 15 . Furthermore, a rotating shaft 16 , which is aligned coaxially with the rotating shaft 14 , is connected to the holding element 13 . One end of the rotating shaft 16 is connected to a drive shaft 19 of a motor 18 by means of a coupling 17 . A motor driver circuit 630 is connected to the motor 18 .

A light beam falls on a side surface of the polygon prism 611 , which is indicated in FIG. 7 by an arrow. The angle of incidence i of this light beam varies in a range between + 45 ° and -45 °, and the degree of dislocation y (see FIG. 1) between the exit position with reference to an angle of incidence i (which is equal to the exit angle) and the position of incidence follows in the following formula (1):

y = d _* sin (i _* (1-1 / n _r )) (1)

where n _{r represents} the refractive index of the substance that forms the polygon prism and d represents the distance between the two opposite surfaces of the polygon prism.

The angle of incidence i varies with the rotational movement of the Polygon prism. This changes accordingly Degree of displacement y. Since in the present case a polygon Prism is used and there in detail Prism with an even number of side surfaces application finds, the change in dislocation returns y every time the position of the incident Beam of a vertex or reached an edge of the prism.  

(1) First embodiment

An optical deflector according to a first embodiment of the invention is described in more detail below with reference to FIG. 1.

According to this embodiment, the optical deflector has a polygon prism 11 which is formed by a regular four-sided prism. The polygon prism 11 is clamped with its opposite end faces between a pair of holding members 12, 13 . The holding element 12 is connected to a rotating shaft 14 which is rotatably supported by a bearing 15 . Furthermore, a rotating shaft 16 , which is aligned coaxially with the rotating shaft 14 , is connected to the holding element 13 . One end of the rotating shaft 16 is connected to a drive shaft 19 of a motor 18 by means of a coupling 17 . A motor drive device 20 is connected to the motor 18 .

A light beam falls on a side surface of the polygon prism 11 , which is indicated in FIG. 1 by an arrow. The angle of incidence i of this light beam varies in a range between + 45 ° and -45 °, and the degree of dislocation between the exit position of the light beam and the position of incidence is determined as a function of the angle of incidence i. That is, in the sense of the exit direction of the light beam based on the formula (1), repeated scanning with the light beam is effected in the vertical direction (in a direction perpendicular to a central axis of the polygon prism 611 ). Since the polygon prism 611 according to this exemplary embodiment is a regular four-sided prism, the scanning is accomplished in two reciprocating movements during one revolution, ie in a total of four cycles.

Since the polygon prism 611 can be made compact in size, it is possible to drive the motor 18 at a high speed, with the result that high-speed scanning becomes possible.

Although with the first Embodiment the polygon prism is a four-sided, it's not like that certain number of side surfaces of the polygon used Prisms prescribed. However, it is necessary that the polygon prism is an even number of Has side surfaces, so that it is ensured that the Directions of incidence and directions of exit parallel will.

In the second exemplary embodiment of the polygon prism shown in FIG. 8, a polygon prism 611 is formed by a regular hexagon prism. In this case, it is possible to keep the number of revolutions at a lower level compared to the case that a regular four-sided prism is used.

Claims (7)

1. Display device for reproducing a two-dimensional image, which is composed of one-dimensional, horizontally running image lines which follow one another in the vertical direction, with a light source ( 631 ), a collimator for collimating the light emitted by the light source, a modulation device ( 632 , 633 ), which modulates the light emitted by the light source as a function of control signals, an optical deflector ( 628 ) which is formed by a regular, n-sided polygon prism ( 611 ) which is rotatable about its central axis, where n is an even number , wherein the central axis runs parallel to the image lines and the collimated and modulated light is incident through one side surface of the polygon prism ( 611 ) and deflected through an opposite side surface with a direction parallel to the direction of incidence, a driver circuit ( 630 ) for the deflector ( 628 ), the rotation of the polygon prism ( 6th 11 ) controls about its central axis for line switching, and a positive lens system designed in the beam path according to the polygon prism ( 611 ), characterized in that the collimator is designed as a reflecting mirror ( 653 ) which converts the light emitted by the light source into a bundle reshaped parallel light beams that the modulation device ( 633, 632 ) has an optical liquid crystal shutter arrangement ( 632 ) which either transmits or shields the parallel light beams incident from the reflecting mirror ( 653 ) for each picture element of a horizontal picture line in accordance with the applied control signals, so that the bundle of parallel beams emerging from the liquid crystal shutter arrangement each represents a complete line of image, that the modulation device ( 632, 633 ) further comprises a collector arranged between the liquid crystal shutter arrangement ( 632 ) and the optical deflector ( 628 ) lens arrangement ( 633 ) which converges the bundle of parallel light rays incident on it near a predetermined axis so that they collapse onto the optical deflector ( 628 ), and that the positive lens system is designed as an eyepiece ( 629 ) that the deflector deflected and depending on the extent of the deflection at different heights of incidence incident on the eyepiece at a predetermined point. 2. Display device for reproducing a two-dimensional image which is composed of one-dimensional, horizontally running image lines which follow one another in the vertical direction, with a light source ( 931 ), a collimator for collimating the light emitted by the light source, a modulation device ( 932, 933 ), which modulates the light emitted by the light source as a function of control signals, an optical deflector ( 928 ) which can be rotated about an axis of rotation which runs parallel to the image lines, the collimated and modulated light incident on and from the deflector ( 928 ) is deflected, a driver circuit ( 952 ) for the deflector ( 928 ), which controls the rotation of the deflector ( 928 ) about its axis of rotation for line switching, and a positive lens system, which simulates the deflector ( 928 ) in the beam path, characterized in that the collimator is designed as a reflecting mirror ( 953 ), de r the light emitted by the light source is converted into a bundle of parallel light beams, that the modulation device ( 933, 932 ) has an optical liquid crystal shutter arrangement ( 932 ) which receives the parallel light beams coming from the reflecting mirror ( 953 ) for each picture element of a horizontal picture line either transmits or shields according to the applied control signals, so that the bundle of parallel beams emerging from the liquid crystal shutter arrangement each represents a complete image line, that the modulation device ( 932, 933 ) furthermore detects a between the liquid crystal shutter arrangement ( 932 ) and the optical deflector ( 928 ) arranged converging lens arrangement ( 933 ), which converges the incident beam of parallel light rays near a predetermined axis, so that they are bundled on the optical deflector ( 628 ) that the deflector ( 928 ) by a reflective End mirror ( 951 ) is formed and that the positive lens system is designed as an eyepiece ( 929 ), which directs the deflected from the deflector and depending on the extent of the deflection at different levels of incidence on the eyepiece at a predetermined point. 3. Display device according to claim 1 or 2, characterized in that the liquid crystal shutter arrangement ( 632 ) has three optical liquid crystal shutter rows ( 632 B, 632 R, 632 G), each of which has a filter ( 644 ), each of which light lets one of the three different main color components through. 4. Display device according to claim 1 or 2, characterized in that the liquid crystal shutter arrangement ( 932 ) has two optical liquid crystal shutter rows ( 932 RB, 932 G), one of which has a filter that transmits light of one of the three different main color components, while the other series of optical liquid crystal shutters ( 932 RB) has two filters that transmit light from the remaining two different main color components. 5. Display device according to claim 4, characterized in that the other optical liquid crystal shutter row ( 932 RB) transmits red light and blue light. 6. Display device according to claim 4 or 5, characterized in that the two filters of the other optical liquid crystal shutter row ( 932 RB) are arranged alternately in the horizontal direction in accordance with each of the individual picture elements of the picture line. 7. Display device according to one of claims 1 to 6, characterized in that the converging lens arrangement ( 633 ) has a predetermined number of cylindrical lenses ( 635, 636 ).