DE19860737A1 - Rear lighting for flat display has micro prism structure on side of light conductor away from display with micro prisms, each with one of two sides closer to light conductor narrow side - Google Patents

Abstract

The arrangement has a wedge-shaped light conductor (11), and light from a source (10) is coupled into a first narrow side (12) of the light conductor. A micro prism structure (16) is arranged on the side (15) of the light conductor away from the display with a number of micro prisms, each with one of two lateral surfaces closer to the first narrow side of the light conductor than the other. The first side of a micro prism has a smaller distance from a prism edge to a first foot than the distance to a second foot on the second side.

Description

State of the art

The invention relates to a device for Backlighting of a flat display according to the genre of the main claim. It is already a device for Backlighting of a flat display from the Publication WO 95/32390 known in the light one rod-shaped light source into an almost wedge-shaped Optical fiber is coupled in via a narrow side the light spreads out under total reflection in the light guide and about reflection on a stair structure at the side of the light guide facing away from the display is coupled out. Furthermore is from the publication EP 0 663 600 known, light from a rod-shaped light source to couple into a wedge-shaped light guide in which Scattering bodies are present, through which light is displayed is redirected. This light guide is on the top a microprism structure attached to the collimation serves the light.  

Advantages of the invention

The inventive device with the features of The main claim has the advantage that the Loss of light when decoupling the light in the direction of the ad can be minimized. The same brightness of the Display compared to conventional backlighting is thus at a reduced power consumption Light source reached. This is particularly the case with off-grid devices an advantage, because in such a Case the maximum operating time from the power consumption the device components is dependent. In addition, the maximum brightness of the display at the same Power consumption compared to a conventional one Backlighting can be increased. By the Side surface of the microprisms facing away from the light source greater extension from the prism edge to that Prism base than that facing the light source Side, the area is increased for the decoupling is available.

By the measures listed in the subclaims are advantageous developments and improvements in Main claim specified device possible. Especially it is advantageous that the prism edges of the microprisms run parallel to the narrow side of the light guide, in which couples the light from the light source. Because there the light in the light guide from the light source spreading, the decoupling can be particularly efficient respectively. In particular, this is an advantage at Backlighting of advertisements with no display area Rectangle, but e.g. B. is designed in a circular arc.

It is also advantageous that the light source is rod-shaped is executed. This is a homogeneous  Coupling of light over an entire narrow side of the Fiber optic possible. A cold cathode fluorescent lamp is for this z. B. a light source with low Power consumption and long life, being one appropriate selection of lamp phosphor the generation of white light and thus the representation of the RGB colors for the backlighting of a colored display enables.

It is also advantageous that the side surfaces of the Microprisms from the narrow side into which the light is coupled, and thus facing away from the light source are at least three times the distance from the Have prism edge to the foot of the prism than that side surfaces facing the light source. By size the side surface facing away from the light source becomes the Prism very flat on this side, so that the Coupling area enlarged and thus a more efficient Decoupling is possible. The one facing the light source Side surface of the prism is minimized as well is not required for the decoupling mechanism. By the flat side of the microprisms now turns to light redirected the side of the light guide facing the display. So the angle of incidence on this page differs very little of the angle of total reflection, so that the light at a flat angle, d. H. approx. 70 ° opposite the vertical, is coupled out.

By for the side surface of the light source Microprisms at an angle to that facing away from the display Area of the light guide from 70 ° to 90 ° and for which the Side surface of the microprisms facing away from the light source Angle from 3 ° to 14 ° with that facing away from the display Surface of the light guide is provided, this can be Effect particularly well. Furthermore, the flat side of the micro prisms suppresses light loss, which at a larger angle this flat side of the  Microprisms opposite the side facing away from the display of the light guide would arise from light rays whose Angle for total reflection on the flat side of the Microprisms is too steep, which means the light guide leave and not be redirected to the display.

It is also advantageous that the base of a microprism maximum one hundredth of the length of the ad side surface of the light guide facing away from the Light source up to the side surface of the light guide which is opposite the side surface into the light the light source can be coupled. By the size of individual Microprisms are kept as low as possible, one large variety of microprisms on the display Attach the opposite side of the light guide and thus to ensure homogeneous illumination of the display.

It is also advantageous to use distances between the To provide microprisms and between the microprisms side of the light guide facing away from the display to lead. It can thus be avoided that in one area of the light guide near the light source already too much light is decoupled. A homogeneous distribution of brightness Display is thus enabled, making it easier to read the ad is improved. Through variable distances between the microprisms, the homogeneity of the display be further improved.

It is also advantageous that the bases of the Microprisms are chosen variably. Because become the bases the microprisms changed, so it can be Execution of the microprisms according to the invention also the Size of the prism and thus change the area for the Coupling of light rays to the display can be used  is. As a result, the homogeneity of the Ad brightness can be further improved.

It is also advantageous that the light guide on the the visible part of the display facing away is arranged, as the light guide when viewing the display does not bother.

It is also advantageous to use the display opposite side of the light guide a reflector to provide. Depending on the light coupling and after Beam path of light in the light guide, it is possible that rays of light are not under total reflection in the Continue the light guide and not towards a display be coupled out, but the light guide at the Leave bottom. Through the reflector you can again be coupled into the light guide and possibly coupled out for display in the further beam path become. By preferably the reflector is non-scattering is executed, the angular direction of the light is on hits the reflector, not changed. This can this light in particular through the invention Execution of the prisms again in an optical Preferred direction are coupled into the light guide, so that the light at the same angle from the light guide can be decoupled under which the light Leaves light guide, which is coupled out for display, without first the light guide on the side facing away from the display Leave side.

It is also advantageous between the display facing surface of the light guide and the display Arrange the film on the side facing the light guide Side has a sawtooth structure. The invention executed micro prism structure gives the light in one  Preferred direction from the vertical to the Optical fiber surface and thus to a display, however lies. For many applications, however, it is desirable that a viewer with an almost vertical view of the display receives the greatest possible brightness of the display. With the It is now foil that has a sawtooth structure possible, the light emerging from the light guide into the Redirect perpendicular. By averting the display Side face of a sawtooth with the plan Foil surface and thus with the base of the sawtooth parallel to the film surface, an angle in a range of 65 ° to 90 ° and that of Side of the saw tooth with the base facing the light source of the sawtooth an angle in a range of 45 ° to 60 ° includes, this redirection is in adaptation to the Microprism structure designed according to the invention in particular quite possible.

Furthermore, it is advantageous between the film and the Display insert a prism film. This prism film serves the further collimation of the light guide or of the foil with a sawtooth structure emerging light.

It is also advantageous between the prism film and arrange a diffuser film on the display. This Diffuser film is used to remove remaining inhomogeneities Eliminate display brightness and a homogeneous Brightness across the entire display area guarantee.

It is also advantageous between the light source and the side surface of the light guide into which the light of the Light source can be coupled in, to arrange a prism film, that collimates the light from the light source. This can  the light of the light source in a defined Angular range can be coupled into the light guide. This angular range is according to the invention designed microprisms and adapted to the light guide, so that both good light conduction with total reflection, as well as an optimized decoupling of the light can be.

It is also advantageous that the side surface of the Light guide has a reflector on the side surface opposite, into which the light of the light source can be coupled. Due to the wedge shape of the light guide already ensures that a large part of the light does not reach reaches this side surface of the light guide, but is previously coupled out by the microprisms. By the However, reflector can emit light from the light source up to to the opposite end of the light guide, reflected back into the light guide and later to Display be coupled out, so that a loss this side surface is minimized.

For certain applications it is advantageous that the Light guide, preferably including the light source, on the side facing the visible part of the ad is arranged. This makes it possible if there is sufficient Ambient brightness the display with the ambient light too backlight and switch off the light source. Enough this brightness does not come off, so the light source be switched on, and a backlighting of the display with the help of the light source is possible. In particular it is advantageous to improve the reflection one to install a scattering reflector behind the display. Especially in applications with a limited Power source, such as B. in mobile operation, so Power consumption of the display can be reduced if one  there is sufficient ambient brightness. Across from conventional front lighting is not Compensation layer more necessary, which otherwise the Influencing the light rays corrected by the Ad get lost to a viewer because of a Influencing the light of the display when in use the flat micro prisms according to the invention is low.

In this case, it is also advantageous to use the Narrow side of the light guide, that of the first narrow side opposed to second an absorber to a To prevent reflection of the light on this narrow side, because this interferes with the reflection at the reflector is avoided on the invisible side of the Display is arranged.

It is also advantageous here to attach the microprisms to the to arrange the side of the light guide facing the display. This applies in particular in the event that the light guide is on the side of the display facing the visible part of the ad Display is arranged. Because in this case, the Microprismatic structure not towards the viewer, and towards one Protection of the microprisms, especially against damage, can be dispensed with.

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the following description. In the drawings Fig. 1 shows an embodiment of the invention the device for backlighting in a cross section in side view, Fig. 2 shows an embodiment of the invention the light guide in plan view on the side remote from the display side of the light guide, Fig. 3 shows an embodiment of the invention a micro-prism in side view. Further, FIGS. 4 and 5 embodiments of the backlighting device according to the invention with a reflector. Fig. 6 shows an inventive embodiment with an inventive film for redirecting the light. Fig. 7, the film of the invention shows in magnification. Fig. 8 shows a further embodiment of this invention showing the backlighting device for use in a liquid crystal display. Fig. 9 shows a further embodiment according to the invention with a prism film between the light source and light guide in a side view. Further, Fig. 10 shows a backlighting device according to the invention with a pointed as possible, wedge-shaped light guide. Fig. 11 shows an inventive embodiment, wherein the backlighting device for a display having a display area is provided which is carried a circular arc. FIG. 12 shows a further exemplary embodiment according to the invention, in which the light guide is arranged on the side of the display facing the visible part of the display. Fig. 13 shows in this respect a further embodiment of this invention.

Description of the embodiment

In Fig. 1 a device for backlighting according to the invention is shown in a cross section. The figure shows a rod-shaped light source 10 , preferably a cold cathode fluorescent lamp, and a wedge-shaped light guide 11 . The light guide 11 has a first narrow side 12 , into which the light from the rod-shaped light source 10 is coupled. Furthermore, the light guide 11 has a first side surface 13 which faces the display (not shown). The wedge-shaped light guide 11 ends on a second narrow side 14 . Microprisms 16 are attached to the second side surface 15 opposite the first side surface 13 ; a microprism is selected for the label here. The light from the rod-shaped light source 10 is coupled into the wedge-shaped light guide 11 through the first narrow side 12 and propagates in the light guide with total reflection. The microprisms 16 serve to deflect the light so that it leaves the light guide through the first side surface 13 and can reach the display (not shown). The light guide 11 is made of a transparent material, for. B. plexiglass (PMMA, polymethyl methacrylate), preferably made by injection molding, the microprisms being molded directly.

FIG. 2 shows the light guide 11 from FIG. 1 with a view of the second side surface 15 . Here and in the following figures, the same designations are intended to denote the same components. Electrical supply lines 20 and 21 are arranged on the light source 10 , via which an electrical voltage can be applied to the light source. The microprisms 16 run parallel to the first narrow side 12 and extend over the width of the entire light guide 11 . The basis of the microprisms is constant across the width of the light guide. In a preferred embodiment of the apparatus shown in Fig. 1 and Fig. 2 for backlighting more microprisms are present in the figure as shown on the light conductor 11. For the sake of clarity of the drawing, this preferred embodiment is not shown. In a light guide, the first narrow side of which extends between 50 mm and 120 mm along the light source 10 and in which a third narrow side 22 and a fourth narrow side 23 have a length of 50 mm to 100 mm, between 200 and 220 microprisms are provided. The microprisms rise above the second side surface 15 . Their height above the second side surface 15 is in a range from 20 to 30 micrometers. The thickness of the light guide, measured between the first side surface 13 and the second side surface 15 , is in the region of the first narrow side 12 in a range from 2.5 mm to 3 mm and in the region of the second narrow side 14 in a range of 0.4 mm to 0.7 mm. The distances and the bases of the prisms are selected to be variable in a special embodiment, so that the first side surface is as homogeneous as possible in brightness. This is also not shown for reasons of clarity in the drawing.

In Fig. 3, a micro prism 16 is shown enlarged from the same viewing direction as in Fig. 1. The microprism 16 rises above the second side surface 15 of the light guide 11 . The microprism 16 has a base 30 , which represents an extension of the second side surface 15 , which is shown in dashed lines in the drawing. The microprism 16 has a first side surface 31 which is closer to the first narrow side 12 of the light guide than a second side surface of the microprism 32 . The first side surface of the microprism 31 forms a first angle 33 with the base 30 of the microprism, which is in a range from 70 ° to 90 °. The second side surface 32 of the microprism forms a second angle 34 with the base 30 of the microprism, which is in a range from 3 ° to 14 °. The microprism 16 also has a base point 35 of the first side surface 31 . Here the first side surface 31 of the microprism reaches the second side surface 15 of the light guide. Furthermore, a base point 36 of the second side surface 32 and a prism edge 37 that is common to both side surfaces is shown. The second side surface 32 preferably has three times the extent from its base point 36 to the prism edge 37 than the first side surface 31 from its base point 35 to the prism edge 37 . The light of the light source 10 coupled in on the first narrow side propagates in the light guide 11 and in particular strikes the first side face 13 of the light guide and the second side face 15 , wherein it is reflected with total reflection. Due to the wedge shape of the light guide, the angles of the light beams with respect to the perpendicular to the two side faces decrease with each reflection on the second side face 15 . If light strikes the second side surface 32 of the microprism, the light can be deflected to the first side surface 13 under total reflection or it can leave the light guide through the side surface 32 .

If the incident light is deflected to the first side surface 13 of the light guide, it can be coupled out of the light guide there. By choosing in particular the second angle 34 , the second side surface of the microprism runs flat relative to the second side surface 15 of the light guide. As a result, the angular range of the light coupled out from the first side surface 13 is small, and the requirements for further collimation are reduced.

If light is coupled out through the second side surface 32 of the microprism 16 , a reflector can be attached to the side 15 of the light guide 11 in order to avoid the loss of this light. Possible arrangements of the reflector are shown in FIGS. 4 and 5.

In FIG. 4, the light source 10, the light guide is shown with the first side surface 13, the second side surface 15, the first narrow side 12 and the second narrow side 14 11. The microprisms attached to the second side surface 15 are not shown in order to simplify the illustration. A reflector 40 is located below the second side surface 15 of the light guide 11 . This reflector runs parallel to the second side surface 15 . It is non-scattering, e.g. B. a mirror, a reflective metal foil or a metal-coated plastic film.

Another embodiment of the reflector is shown in FIG. 5. While the remaining description relative to FIG. 4 remain the same, a reflector 50 is disposed parallel to the first side surface 13 of the light guide. The reflector 50 is also non-scattering. In the two arrays in Fig. 4 and Fig. 5, light which exits the light guide through the second side surface 15 or by the microprisms 16 and is not coupled to the first side surface 13 side, thrown back into the light conductor 11. The angles of the prisms and the angles of the reflector can be selected so that the light reflected back into the light guide is deflected in the same angular range as that from the second side surface 32 of the microprism to the first side surface 13 of the light guide. A further collimation can thus largely be dispensed with. The light that leaves the light guide through the second side surface 15 can be used for backlighting the display except for the losses on the non-scattering reflector 50 .

In Fig. 6 a section of the light guide 11 to the first narrow side 12, the first side surface 13 and the second side surface 15 is shown. Between the first side surface 13 and the display (not shown) there is a film 60 with a sawtooth structure on the side facing the first side surface 13 of the light guide 11 . Since the light from the first side surface 13 of the light guide is coupled out at an angle with respect to the perpendicular to the first side surface 13 that lies in a range between 60 ° and 80 °, the film serves to direct the light perpendicular to the first side surface 13 in the direction of the Redirect ad. This is necessary in particular because a user of a display generally wants the maximum brightness when viewing the display vertically.

A saw tooth 70 of the film 60 from FIG. 6 is shown enlarged in FIG. 7. The sawtooth 70 has a first side surface 71 and a second side surface 72 . A base of the saw tooth 73 is shown in dashed lines. Furthermore, a side surface 76 of the film 60 is shown, which runs flat and parallel to the first side surface 13 of the light guide. The first side surface 71 of the sawtooth 70 forms a first angle 74 with the base, which lies in a range from 65 ° to 90 °. The second side surface 72 forms a second angle 75 with the base 73 , which lies in a range from 45 ° to 60 °. The light emerging from the first side surface 13 of the light guide 11 is incident on the first side surface 71 of the sawtooth, which is approximately perpendicular to the first side surface of the light guide and to the surface. The light is then redirected by a total reflection on the second side surface 72 of the sawtooth to the side surface 76 of the foil and leaves the foil 60 through the side surface 76 , the side surface 76 facing the display.

For displays in which the maximum brightness is to be achieved at a viewing angle which is at a distance from the vertical, the sawtooth structure can either be modified by reducing the first angle 74 and increasing the second angle 75 , or even completely omitted. Possible areas of application for this are e.g. B. embedded in a lane, which should be recognized by a driver at a flat angle relative to the lane.

In FIG. 5, a device according to the invention is shown for backlighting a liquid crystal cell in a cross section. 10 denotes the rod-shaped light source, 11 the light guide, 12 the first and 14 the second narrow side, and 13 the first and 15 the second side surface of the light guide. The microprisms, which are located on the second side surface 15 , are not shown for reasons of clarity. A reflector 40 is arranged on the second side surface 15 . This can also be replaced by the reflector 50 shown in FIG. 5. A reflector 81 is arranged around the lamp. Furthermore, a reflector 82 is arranged on the second narrow side 14 of the light guide. The film 60 with the sawtooth structure facing the first side surface 13 of the light guide can be seen above the first side surface 13 , the sawtooth structure likewise not being shown here. Above this is a prism film 83 , which is used for further collimation of the light. This prism film is e.g. B. a film that is flat on the side 13 facing the first side and on the opposite side has microprisms that run parallel or crossed to the microprisms 16 . The microprisms of the prism film 90 are preferably symmetrical, ie both prism flanks are of the same length. A diffuser 84 is optionally arranged after the prism film 83 . In FIG. 8, the distances between the three sheets 60, 83 and the diffuser are shown enlarged 84; In a preferred embodiment, these foils are placed directly on top of one another in the device. A liquid crystal cell 85 is shown above the diffuser 84 . As a function of voltage applied to a non-illustrated control electronics control signals of the liquid crystal cell 85 can be the steered from the light source 10 via the optical fiber 11 and the films 60, 83 and 84 to the liquid crystal cell 85 light influenced with respect to its transmission through the liquid crystal cell 85 in detail, not illustrated pixel elements become. For this purpose, an electrical field is applied to the liquid crystal molecules in the individual, separately controllable pixel elements of the liquid crystal cell 85 via the control electronics, by means of which a crystal structure of the liquid crystal molecules and thus their optical properties with regard to the transmission of polarized light can be changed. Polarizers (not shown) for generating or absorbing polarized light, preferably polarizer foils, are arranged on the liquid crystal display 85 . Image information can thus be displayed. The reflector 81 serves to better couple the light from the rod-shaped light source 10 into the light guide 11 . The reflector 81 is preferably a white reflector made of a plastic material or a reflective film with a metal layer. It can, as shown in FIG. 8, be designed with angular edges. Furthermore, it is possible, but not shown in the drawing, to design the reflector to be adapted to the lamp. The reflector 82 serves to reflect light emerging on the second narrow side 14 back into the light guide 11 . The diffuser 84 ensures better homogeneity of the display brightness. The diffuser 84 is preferably designed as a scattering, thin plastic film, for. B. a film with a rough surface or a scattering print. The prism film 83 serves for further collimation of the light, so that the light strikes the liquid crystal cell approximately perpendicular to the liquid crystal cell 85 . Instead of the liquid crystal display, there is also a fixed display, e.g. B. a slide or a transparent plastic film can be used.

In Fig. 9, a prism film 90 is attached between the rod-shaped light source 10 and the first narrow side 12 of the light guide 11 , which collimates the light from the light source 10 , so that the light rays can only enter the light guide 11 in an angular range predetermined by the prism film 90 . The coupling mechanism is thus improved via the microprisms 16 and the light emerging from the first side surface 13 of the light guide is collimated. Prisms are arranged on the prism film on the side facing away from the light source. The side facing the light source is flat. The prisms are preferably symmetrical, ie the prism flanks are of the same length.

FIG. 10 shows a rod-shaped light source 10 with a light guide 100 which, like the light guide 11, has microprisms according to the invention on a side surface 101 , which are not shown here for reasons of clarity. The special feature of the light guide 100 compared to the light guide 11 in FIG. 1 is that it ends in a pointed edge 102 . In this way, light losses can be avoided, which can occur in the light guide 11 by coupling out on the second narrow side 14 .

FIG. 11 shows a further embodiment of a light guide 113 with a curved light source 110 , which has electrical connections 111 and 112 , in a view of the side of the light guide facing away from the display. The light guide 113 is designed in the form of an arc of a circle. Microprisms 114 according to the invention also run parallel to the light source here. The arrangement shown in FIG. 11 also makes it possible to backlight displays that do not have a rectangular display area. A liquid crystal display for a display instrument in a vehicle can be mentioned as a possible application for this. Furthermore, it is possible to arrange several displays over one light guide 113 .

FIG. 12 shows a device for backlighting according to the invention, in which the light source 10 and the light guide 11 are arranged on the side of a display which is visible to a user. In Fig. 12 the light guide is disposed on the visible side of the liquid crystal display 85th The light from the light source 10 is coupled into the first narrow side 12 of the light guide 11 and is coupled out through a second side surface 123 through the microprisms according to the invention arranged on a first side surface 122 facing away from the display, for liquid crystal display 85 . The light which is not coupled out of the light guide 11 is emitted on the narrow side 14 opposite the first narrow side 12 by an absorber 121 arranged there, e.g. B. a black layer of paint. Light reaching the liquid crystal display 85 is absorbed there or 85 of the individual pixel elements of the liquid crystal cell depending on a state of the liquid crystal cell or reaches a scattering reflector 120th This scatters the light and thus redirects part of the light, as a result of which the liquid crystal cell 85 backlit and the light thereafter crosses the light guide 11 and can finally reach a user of the display. In order to protect the microprisms, a protection, not shown, is provided on the first side surface 122 of the light guide. B. a transparent plastic film.

In FIG. 13, as in FIG. 12, the light guide is arranged on the visible side of the display. In contrast to FIG. 12, however, the microprisms according to the invention are arranged on a side surface 130 of the light guide 11 facing the display in FIG. 13. A preferably flat second side surface 131 faces away from the display. For the backlighting of the liquid crystal display 85 , it is not the light that is coupled out that couples the microprisms on the first side surface 130 toward the second side surface 131 , but the light that leaves the first side surface 130 toward the liquid crystal display 85 . The further mode of operation corresponds to the exemplary embodiment shown in FIG. 12.

Claims (24)

1. Device for backlighting a flat display ( 85 ) with a wedge-shaped light guide ( 11 , 100 , 113 ), whereby light from a light source ( 10 , 110 ) can be coupled into a first, wide narrow side ( 12 ) of the wedge-shaped light guide, thereby characterized in that a microprism structure with a plurality of microprisms ( 16 ) is formed on a side surface of the light guide ( 15 , 122 ) facing away from the display, the microprisms each having a first side surface ( 31 ) and a second side surface ( 32 ), wherein in each case the first side surface ( 31 ) has a smaller distance from the first narrow side of the light guide ( 12 ) than the respective second side surface ( 32 ), each first side surface of a microprism from the prism edge ( 37 ) to a respective first foot of the prism ( 35 ) each has a smaller distance than the respective second side surface of the microprism to a j Eternal second foot of the prism ( 36 ). 2. Device according to claim 1, characterized in that the prism edges of the microprisms ( 37 ) run parallel to the narrow side of the light guide ( 12 ), into which the light of the light source ( 10 , 110 ) can be coupled. 3. Device according to one of the preceding claims, characterized in that the light source ( 10 , 110 ) is rod-shaped, in particular a cold cathode fluorescent lamp. 4. Device according to one of the preceding claims, characterized in that every second side surface of a micro prism ( 32 ) in relation to the associated first side surface of a micro prism ( 31 ) at least three times the distance from the prism edge ( 37 ) to the respective foot of the prism ( 35 , 36 ). 5. Device according to one of the preceding claims, characterized in that the first side surface of a micro prism ( 31 ) with a base of the micro prism ( 35 ) includes an angle ( 33 ) facing away from the light source in a range of 70 to 90 degrees. 6. Device according to one of the preceding claims, characterized in that the second side surface of a micro prism ( 32 ) with a base of the micro prism ( 35 ) includes an angle ( 34 ) facing the light source in a range of 3 to 14 degrees. 7. Device according to one of the preceding claims, characterized in that the microprisms have a base ( 35 ) which is at most one hundredth of the length of a first side surface of the light guide ( 13 ) from the light source ( 10 ) to a second narrow side of the light guide ( 14 ), which lies opposite the first narrow side ( 12 ), into which the light from the light source can be coupled. 8. Device according to one of the preceding claims, characterized in that distances are provided between the individual microprisms ( 16 ). 9. The device according to claim 9, characterized in that the distances between the microprisms are chosen such that the microprisms occupy a maximum of three quarters of a second side surface of the light guide ( 15 ) which faces away from the display. 10. Device according to one of claims 9 to 10, characterized in that the distances between the microprisms are variable depending on their distance to the first narrow side of the light guide ( 12 ). 11. Device according to one of the preceding claims, characterized in that the microprisms have bases ( 35 ) which are selected as a function of the distance to the first narrow side of the light guide ( 12 ). 12. Device according to one of the preceding claims, characterized in that the light guide ( 11 ) is arranged on the side of the display facing away from the visible part of the display. 13. Device according to one of the preceding claims, characterized in that the light guide on the side facing away from the display has a reflector ( 40 , 50 ) which is preferably non-scattering. 14. Device according to one of the preceding claims, characterized in that between the first side surface of the light guide ( 13 ), which faces the display, and the display, a film ( 60 ) is arranged, which on a first side facing the light guide Sawtooth structure with a plurality of saw teeth ( 70 ) and is flat on a second side ( 76 ) facing the display. 15. The apparatus according to claim 14, characterized in that the saw teeth ( 70 ) have a first, the light source side surface ( 71 ) and a second, the light source side surface ( 72 ), the first side surface to a base of the saw tooth ( 73 ) lies at a first angle ( 74 ) facing away from the light source in a range of 65 to 90 degrees and the second side surface to the base of the sawtooth ( 73 ) lies at a second angle ( 75 ) facing the light source in a range of 45 up to 60 degrees. 16. The device according to one of claims 14 to 15, characterized in that a prism film ( 83 ) is arranged between the film ( 60 ) and the display ( 85 ). 17. The apparatus according to claim 16, characterized in that a diffuser ( 84 ) is arranged between the prism film ( 83 ) and the display ( 85 ). 18. Device according to one of claims 1-15, characterized in that a prism film ( 90 ) is arranged between the light source and the first narrow side ( 12 ) of the light guide. 19. Device according to one of the preceding claims, characterized in that the second narrow side of the light guide ( 14 ) has a reflector ( 82 ) which lies opposite the first narrow side of the light guide ( 12 ). 20. Device according to one of claims 1-11, characterized in that the light guide ( 11 ) is arranged on the side facing the visible part of the display. 21. The apparatus according to claim 20, characterized in that a reflector ( 120 ) is arranged on the side of the display facing away from the light guide, which is preferably designed to be scattering. 22. The device according to any one of claims 20-21, characterized in that the second narrow side of the light guide ( 14 ) has an absorber ( 121 ) which lies opposite the first narrow side of the light guide ( 12 ). 23. Device for backlighting a flat display ( 85 ), with a wedge-shaped light guide ( 11 ), light from a light source ( 10 ) can be coupled into a first, wide narrow side ( 12 ) of the wedge-shaped light guide, characterized in that on one of the A microprism structure with a plurality of microprisms ( 16 ) is formed on the side face of the light guide ( 130 ) facing the display, the microprisms each having a first side face ( 31 ) and a second side face ( 32 ), the first side face ( 31 ) each having one has a smaller distance from the first narrow side of the light guide ( 12 ) than the respective second side surface ( 32 ), wherein each first side surface of a microprism has a smaller distance from the prism edge ( 37 ) to a respective first foot of the prism ( 35 ) than the respective second side surface of the microprism to a respective second foot of the prism ( 36 ). 24. The device according to claim 23, characterized in that the light guide ( 11 ) is arranged on the side of the display facing the visible part of the display.