KR100795447B1 - Light guide, light guide appratus, light guide system and method of manufacturing the same - Google Patents

Abstract

The present invention relates to a method, an apparatus, a system and a light guide, and more particularly to a backlighting or frontlighting light guide for user interfaces of electronics. In order to enable mass production at low production costs, the light guide substrate is provided in a continuous foil, and the diffraction gratings are embossed on at least one side of the foil by rolling.

Description

Light guide, light guide appratus, light guide system and method of manufacturing the same}

The present invention relates to a method of manufacturing a light guide, and more particularly to a method of manufacturing a backlighting or frontlighting light guide for user interfaces of electronic devices. The present invention also relates to a light guide manufacturing system and a light guide manufacturing apparatus. The present invention relates to a light guide produced by the above method.

Non-luminous display technologies, such as consumer electronics, communication devices, advertisements or signs and road signs, require an illumination system that produces a display that is identified in low light conditions. In order to provide illumination, several different techniques are known. In transmissive or partially transmissive (eg transflective) display technologies such as, for example, liquid crystal displays (LCDs), the display is known to be illuminated using suitable light guides (LG). These light guides may be arranged behind the light modulating display to implement a backlighting light guide. It is also known to form so-called frontlighting in front of the reflective display.

In order to provide a backlight or frontlight light guide, it is known to use diffractive optics. Such diffractive optics are disclosed in EP 1 016 817. Thus, the known arrangement uses "thick", "plate-like" light guides, one end of which has a light source, and / or on the flat one side of the largest area plate and / or inside the light pipe There is an illuminated object for uniform illumination.

It is known to use a thin plate-shaped light guide from one end of which the light source emits light into the space between the upper and lower surfaces of the light guide. The bottom surface of the light guide may be roughed randomly or continuously. This rough surface causes the viewer to illuminate the corresponding object located above the upper surface of the display or light guide in the direction of the viewer. Roughening one surface causes light to be scattered as uniformly as possible in the display direction. Roughening can be performed randomly or continuously. Such diffractive light guides allow for uniform illumination of the displays. However, randomly roughening the surface can cause problems with uniformity of light.

US Pat. No. 6,598,987 discloses a system for distributing light in a thin light guide. This system uses diffraction gratings as a means of optically coupling light from a light source such as light emitting diodes (LEDs) to a light guide. Using diffraction gratings or the like as the coupling mechanism, the thickness of the light guide is significantly reduced, and the coupling efficiency is increased. A system is provided that utilizes light emitted from an array of LEDs through a circuit board to enable coupling of light into the light guide. Light is coupled into the light guide by use of input diffraction optical elements (DOE), such as diffraction gratings associated with the light guide. If the light guide is thicker (eg, approximately the thickness of the height of the LEDs, or thicker), by means of so-called side firing, using the LEDs on one side of the light guide, at the same time, the light guide In-coupling can be achieved using a diffraction grating to evenly emit light from a specific area of.

Using an appropriate optical relationship, the input grating pattern is designed taking into account the respective spectra and dimensions of the LED, the dimensions and structure of the light guide, and the amount of light required. Diffraction gratings are formed above or below the light guide, depending on which side the light source is positioned to receive light emitted from the diode. These gratings provide the ability to diffract light consistent with the properties of the light guide to efficiently distribute the light within the light guide. In order to provide diffraction gratings in the light guide, a master grating pattern is formed, for example by electron beam lithography, and simulated on the light guide in the molding or pressing process of the light guide. The "original" is not primarily used directly, but its replica is used. Thus, in the event of a "failure" the disc can be used to make a new "mold". Thus, light guides can be fabricated using integrated in-coupling and out-coupling diffraction gratings, and can provide light guides having a thickness between 0.2 and 1.5 mm. However, thinner or thicker light guides are also possible.

However, pressing or molding the diffraction gratings into the light guides has the disadvantage that the process is not continuous. Moreover, when pressing or molding the diffraction gratings into the light guides, extra optical films have to be added to the light guide in the additional manufacturing process. This manufacturing process adds additional cost and is time consuming.

In order to overcome the above disadvantages, the present invention proposes a method of manufacturing a light guide, and in particular, a method of manufacturing a backlighting or frontlighting light guide for user interfaces of electronic devices. The light guide substrate is provided as a foil, and the diffraction gratings are embossed on at least one side of the foil by rolling.

The light guide substrate may be any material capable of guiding light efficiently and is known in the art. Providing this substrate as a foil allows for continuous provision of the light guide material. The foil can be further processed in succession by rolling. Rolling may emboss diffraction gratings on at least one side of the foil. Thus, the light guides may be manufactured in a continuous process. The thickness of the plastic substrates used may be 0.5 to 0.6 mm or less. If the light can be coupled using an efficient method, for example diffractive in-coupling elements, physically limiting the thickness of the light guide only to the wavelength of the light used, and thus 0.1 to 0.2 mm thick light guides It is also possible. Thus, the "printing" of the diffraction gratings may be performed in a continuous web. In particular, foils having a thickness between 0.1 mm and 3 mm are preferred. However, thicker foils are also possible. In this case, it is particularly desirable to provide the foils as sheets rather than to provide the foil from bobbins.

A continuous pattern of light guides (ie individual light guides that are later cut off from the network) are based on diffraction gratings / patterns within a predetermined area (eg, 3 cm × 2 cm). Thus, this area may often be copied onto a continuous network, such as having space (considering having the required boundary area and mechanical design).

In the case of diffractive light guides, the use of the word "roughening" may not be appropriate because it is often referred to as a "random or chaotic" surface structure. Grooves in the diffraction pattern may have well defined dimensions (depth and width), and thus the pattern to provide optimal performance (eg, for a constant out-coupling area and thickness of the light guide). Is calculated mathematically.

If the diffraction gratings are embossed into the foil in a continuous pattern, the resulting light guide may have improved optical properties. However, it is also possible to emboss a discontinuous pattern into the foil, which may be formed by discontinuously adjusting the rolling rolls according to a desired pattern. Nevertheless, if the rolls provide a continuous embossing pattern, the continuous pattern may be used to continuously emboss the diffraction gratings.

The backlight light guide is located behind the display through which light is transmitted. In addition, a front light guide is also possible. The frontlight light guide is positioned in front of the display that reflects light from the light guide.

In order to provide the foil continuously, it is proposed to provide the foil for rolling from the bobbin. Thus, the length of the foil to be embossed may be limited only by the size of the bobbin.

In order to improve the optical properties of the light guide, it is proposed to partially laminate additional optical films on the embossed foil after rolling. This may be done in a single process step. A plastic substrate is provided from the bobbin and guided through the embossing portion as it is rolled, so that optical films are provided, for example, on either side of the foil, and the final light guide foil is laminated in the laminate portion.

For the continuous provision of the foil, it is proposed that the additional optical films are also provided for the laminate in succession from the bobbin. In the case of a frontlight light guide, the laminated foils may be only protective layers on at least one side.

It is preferable that the optical film and the foil have the same length. This allows the light guide to be processed continuously.

It is also proposed that the additional optical films are partly laminated onto the embossed foil by heating and / or gluing. However, any other laminate treatment is within the scope of the present invention.

Since the foils may not be laminated over the entire area, as they may impair the function of the light guide, the optical films may be at least partially along the outer edge of the foil, or at least partly in the corners of the segments of the foil. It is proposed to laminate to them, or to any suitable locations. Laminating foils together at specific points or areas along the boundaries of the light guide provides excellent results.

An improvement in the optical properties of the light guide is provided by laminating additional optical films on at least one side of the foil. This can be done on the first or second side of the foil.

On the side where the optical gratings are embossed, it is proposed that at least a diffuser film and / or a brightness enhancement film (BEF) will be laminated. It is also proposed that the reflective film be laminated on the other side of the foil. The optical performance of the display system including the light guide can be improved by the use of optical films. The brightness and other optical properties of the light guide may be improved by adding diffusion and brightness enhancing films. In the case of a frontlight light guide, it is preferable to laminate at least one protective film on the front side of the foil. These films may be polycarbonate or PMMA.

In diffraction out-coupling, the light guide system starts from the bottom surface, first with a reflector, a light guide having a diffraction pattern on the side facing the reflector (ie downward), and two luminance on top of the light guide. It is preferred that the enhancement films (and possibly other optical films) be assembled to be arranged. However, both directions, ie, below / above the diffraction grating, can be used to orient the light guide. Which orientation is used depends on the "preference" such as the application to which the light guide of the present invention is applied.

In the case where all the foils are laminated, the light guides may be separated from the continuous foils by cutting, laser cutting, and / or stamping. Therefore, it is proposed that the individual light guides of the foil are separated from the foil by stamping or cutting. It is desirable to combine the laminate in one step with the separation of the light guide. Therefore, it is proposed that during the laminate the individual light guides will be separated from the foil. This means arranging the laminate and cutting / stamping tools in specific locations where it is possible to process the foils simultaneously.

When diffraction coupling gratings are embossed into the foil by the rolling, to provide a coupling of light from the lighting element that illuminates substantially perpendicular to the surface of the foil, perpendicular to the surface of the foil. Or it is possible to couple in light from LEDs arranged in any other angular distribution. The diffractive coupling grating is arranged to provide good in-coupling properties. In-coupling is preferred when the light guide is thin, ie thinner than the height of the LEDs. Alternatively, for thicker light guides, it may still be possible to use "side firing" LEDs at the edge / one side of the light guide.

To allow for good in-coupling properties, during the same process in which the light guide is cut or stamped from the foil, holes for the LEDs may be formed by stamping or cutting additional foils. Thus, while the light guides are segmented, it is proposed that through holes are formed by cutting at least one of the optical films at the positions of the diffraction coupling gratings. Fast manufacturing is possible when the foil is rolled at a speed of 0.1 to 100 m / min, or other suitable speed. Preferred speed is 15 m / min.

In the case of using the side emitting LEDs, that is, side firing LEDs and the through holes together, the LEDs are preferably located completely in the light guide. That is, the holes are preferably stamped through all layers, or at least deeply embossed into the light guide, such that the LED is substantially completely inserted into the light guide.

If a diffractive in-coupling element is used to couple the light into the very thin light guide, the hole of the additional film (s) can be located in the position of the in-coupling diffractive element before the lamination is performed. At least one of these additional "optical films" is first cut / stamped.

It is also preferred that the gratings are embossed by known rolling methods, rotogravure, offset or flexo-printing. It may also be possible to trap a shim around a roll in a hot press to emboss the gratings. It is also desirable to use a rolling technique that can directly pattern the embossed rolls. This may be done by direct laser patterning or custom embossing roll development. Instead of securing the embossing plate (or wedge) around the embossing roll, such customizing techniques may be used.

Another suggestion is to use embossing plates when the height of the gratings is 0.1 to 1 μm. However, higher surface reliefs are also possible. Higher / deeper gratings may be used if temperature and pressure, and “print” speed, are adjusted as more embossing of the deeper gratings is required.

Preferred materials for use in the foil and / or the optical films are polycarbonate, polymethylacrylate, polyvinylchloride, polyethylene, polyethylene terephthalate, or thermo It is a thermoplastic polyester. Compositions as well as these materials may be used in the foils and films.

For good out-coupling of light, it is proposed that the foil and / or the optical films have a refractive index between 1.3 and 1.8. Other refractive indices may also be included within the scope of the present invention.

As mentioned above, the rolling process may be adjusted by adjusting the rolling temperatures. Therefore, it is proposed to adjust the rolling temperature to allow embossing of the gratings into the foil at the rolling speed.

In order to allow a flexible design of diffractive light guides, it is proposed that parts of the foil comprise diffraction gratings, and other parts of the foil comprise other elements, such as electrical, electronic and / or opto-electronic components. It is suggested to do. They are printed on the parts of the foil. Therefore, the foil may be used as a substrate for printed circuits. Print conductive lines, print registers, capacitors, or even print transistors may be printed on the foil with the gratings. The printing process may be integrated into a process such as rolling. Printing of electrical, electronic or opto-electronic components may be possible in a rolling process by separate rolls or in an additional printing process before or after rolling the gratings. Additional printing processes may be inkjet or screen printing processes. Thus, the foil may be used as a flexible printed wiring board.

It is also proposed that portions of the foil extend in order to be used as a means of transmitting optical signals and / or light to out-coupling elements. This may be used for data transfer or for delivering light to other elements where light is coupled out. This may be light coupled out at the keys of the mobile phones.

The use of a rolling process enables mass production of light guides. It is possible to laminate different foils together in the same process. The thickness of the plastic substrates used in the light guide manufacturing method of the present invention may be up to 0.5 mm or thicker. This may allow the light guide substrate to be used with lateral emitting LEDs. This may work with currently available 0.6 mm thick LEDs. LEDs are also higher than the thickness of the light guide, but may reduce the efficiency of in-coupling. Even thinner light guides are possible. In this case it may be desirable to use diffractive in-coupling elements embossed into the foil. The rolling process may be used to emboss diffraction light guides and laminate additional optical foils in a single and extremely cost effective mass production process.

According to another aspect of the invention, a light guide manufacturing device, in particular a device for manufacturing a backlight or frontlight light guide for user interfaces of electronics, comprises at least a first supply means for providing a light guide substrate as a foil and at least a portion of the foil. Rolling means for embossing the diffraction gratings on one side.

This device enables mass production of light guides in the rolling process.

According to another aspect of the present invention, a light guide manufacturing system, in particular a system for manufacturing a backlight or frontlight light guide for user interfaces of electronics, includes at least one side of the foil and supply means for providing the light guide substrate as a foil. And rolling means for embossing the diffraction gratings.

According to another aspect of the invention, a light guide, in particular a backlight or frontlight light guide for user interfaces of electronics, is produced by embossing diffraction gratings on at least one side of the foil of the light guide substrate by rolling. Further, a mobile communication device such as a mobile telephone including a light guide is an aspect of the present invention.

In particular, the present invention can provide a high quality light guide for electronic devices such as mobile phones. Other electronic devices providing a backlight may also use the light guide according to the invention.

The invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram of a device according to the invention.

2A and 2B show light guide segments with laminate points.

3 is a cross-sectional view of a display using a light guide.

4 is a schematic diagram of ultraviolet-lithography that produces a master.

5 shows the segmentation of the light guides.

6 shows various segments of light guides.

7 shows the light guide segments cut longitudinally.

8 shows a light guide means for delivering light to the keys.

9 illustrates a flexible printed wiring board including diffraction gratings.

1 shows a system for rolling a light guide according to the invention. The apparatus comprises bobbins 6, 12, 14, a rolling part 4, and a laminate part 16.

Further shown are the foil of the light guide substrate 2, the first optical film 8, the second optical film 10 and the resulting light guide system 18.

The resulting light guide system 18 is manufactured as follows. From the bobbin 6, the foil of the light guide substrate is continuously provided to the rolling section 4. In the rolling section 4, the foil 2 is embossed by rolling to realize diffraction gratings on at least one side of the foil 2. The diffraction gratings allow controlled and flat out-coupling of light from the light guide 18. The pattern of diffraction gratings is mathematically calculated to provide optimum optical performance for a particular design and light guide thickness. Diffraction and in / out coupling elements may be included in the gratings. The grid can be different, i.e. can be optimized for different purposes.

After rolling the foil 2 in the rolling part 4, the bobbins 12, 14 may provide the optical films 8, 10 on either side of the foil 2. The optical film 8 may be a diffuser film or a brightness enhancement film (BEF). In addition, the optical film 8 has an orientation of 90 degrees inclined with respect to each other, that is, one in parallel with the direction of the light guide and the other in the direction perpendicular to the direction. Two optical films such as BEF). One or more bobbins 12 may also be provided which can provide two or more optical films 8 on one side of the foil 2. On the underside of the foil 2 there is provided another optical film 10, which may be a reflector film. The foil 2 is continuously provided to the laminate part 16 together with the optical films 8 and 10 to enable continuous manufacture of the light guide 18. Optical films do not need to be completely transparent.

In the laminate part 16, the foil 2 is laminated together with the optical films 8, 10. Within the laminate portion 16, the individual light guide system 18 is cut or stamped from the laminated foils (not shown). As shown in FIG. 2, this allows for the integrated manufacture of individual light guides.

Embossing diffraction gratings into the foil and further processing the foil by laminate enables mass production of light guides.

2A is a plan view of an individual light guide 24. Diffraction elements are schematically shown diagonally in the light guide 24. On the foil 2, the optical films 8, 10 are not laminated to the entire surface, but instead are laminated to certain laminate points 20. As shown in FIG. 2A, laminate points 20 may be located in the corner of each light guide segment 24.

2B similarly shows the light guide segment 24. However, the optical films 8, 10 on the foil 2 are laminated slightly differently. As shown, the laminate segments 22 run along the edges of the segment 24, whereby the foil 2 is properly secured with the optical films 8, 10. Through holes 26 are further shown in FIG. 2A. These through holes 26 allow in-coupling of light from upward or side firing LEDs. If diffractive in-coupling elements are used, the holes may be openings in at least one of the optical films, thereby exposing the diffractive in-coupling element of the light guide. That is, "through holes" 26 (ie, openings of optical films) may be arranged such that in-coupling gratings can be positioned at an embossed position into the foil (2). In the case of lateral emitting LEDs, the through holes may be formed through the entire light guide, or at least cut to a depth so that the LEDs can be fully inserted into the light guide.

3 is a cross-sectional view of a display of a user device, in particular a mobile portable telecommunication device. The foil 2 is shown with the optical films 8, 10 laminated on either surface of the foil 2. Further illustrated are through holes 26, diffractive in-coupling element 27, light emitting diode 28, printed wiring board (PWB, 30), liquid crystal display 32 and connector 34. It is.

The connector 34 connects the flexible printed wiring board 30 to a wire different from the power supply device. On the printed wiring board 30, upward emitting LEDs 28 emitting light to the surface of the foil 2 are provided. As shown in FIG. 3, the optical film 8 includes a through hole 26 at the position of the diffractive in-coupling element 27. This allows in-coupling of light from the LED 28 into the foil 2. By in-coupling the light of the LED 28 through the diffractive in-coupling element 27 into the light guide 2, the LCD 32 may be backlit. However, especially when the light guide is thick enough, lateral emitting LEDs may be used at one edge / one side of the light guide. In this case, the diffractive in-coupling element may be omitted.

In order to improve the illumination characteristics, the foil 2 is laminated with the optical films 8, 10. The optical film 10 may be a reflective film, while the optical film 8 may be a diffuser film or a brightness enhancement film (BEF), or two brightness enhancement films (BEF) with appropriate orientations. ), Or both.

The light guide comprising the foil 2 and the optical films 8, 10 may be manufactured in a mass production process according to the method of the invention. This can greatly reduce the manufacturing cost. A continuous process is possible by rolling diffraction elements onto the foil 2. In addition, within the same process, optical films 8 and 10 may be laminated onto the foil 2 and the individual light guides may be cut or stamped from the continuous foil.

4 shows a method of etching a rolling master. Steps 36 to 54 are shown schematically to etch the final structure from the photoresist layer 60. In a first step 36, ultraviolet (UV) -light 56 is irradiated onto a substrate 62 including a photoresist layer 60, an etching mask 59, and a mask substrate 58. Photoresist layer 60 may be exposed by UV-light 56 such that etching mask 59 may be mapped onto photoresist layer 60.

In the developing step 38, the mask 59 is developed, thereby forming regions in which the photoresist layer 60 is present and regions in which they are not. The resulting structure is shown in step 40.

Thereafter, the final structure can be formed in two possible ways 42a and 42b. In the material deposition method 42a, material may be deposited onto the remaining photoresist layer 60 in step 44. The deposited material may cause the residual photoresist layer 60 to lift off in step 46. The resulting structure 48 includes gratings that represent the negative of the final diffraction grating pattern or the planned diffraction pattern.

In the etching process 42b, the substrate 62 is exposed to the etchant along with the photoresist layer 60. As a result, the substrate 62 is removed at the position where the photoresist layer 60 does not exist on the substrate 62. After the photoresist layer 60 is removed in step 52, the final structure 54 is achieved. The structure may also be final diffraction gratings or their negatives.

As shown in FIG. 4, the method of manufacturing the diffraction gratings is based on general lithography methods. Alternatively, the manufacture of surface reliefs may be based on direct display techniques such as laser beam or electron beam display, without the use of shadow masks, as in the case of UV-lithography. The fabricated gratings may be final diffraction gratings or may be negative of the planned diffraction gratings.

A substrate having diffraction gratings produced by the method according to FIG. 4 may sometimes be called a master. The master may be copied directly to the substrate, or may be copied first for the production of multiple objects of the same surface structure. A method for manufacturing masters using the above method and the simulation or duplication of these masters is disclosed in "Diftractive optics: For Industrial and Commercial Applications" Jari Turunen, Frank Wyrowski, Akademieverlag GmbH, Berlin 1997. Masters used in mass production processes may often be referred to as shims, stampers, rollers, and the like, which are used in mass production processes in this way.

In order to realize embossing by rolling, the diffraction grating pattern must be copied to the roller plate, which is trapped around the embossing roll. Depending on the size of the plate, the designed pattern, or many similar patterns, may be manufactured directly onto the plate using one of the above manufacturing processes. When the number of simulated articles to be manufactured is large, it may be preferable to use two or more masters. Alternatively, if the plate is large, or if the plate exceeds the size that can be used for the formation of the master, a small sized disc may be used to copy the same pattern several times on the plate.

5 schematically illustrates the fabrication of other continuous diffraction grating patterns to be cut to an appropriate size. The foil 2 is rolled into two or more continuous strips of diffraction grating patterns L1, L2, and L3. Other lengths of the light guides may be due to other LEDs emitting light of different intensity into the light guides. By rolling different successive diffraction grating patterns of various "optical lengths" (Ll, L2, L3), a large variety of light guide sizes may be cut from the same network. The light guide dimensions available in a single rolling section may range from light guides for small mobile phones to large billboards and / or posters requiring large LCD televisions or backlights or frontlights. The diffractive out-coupling design is naturally optimized for each "optical length" and / or substrate material and / or light source used respectively.

6 shows light guides with different widths wl and w2. Different widths wl, w2 can be achieved by cutting the net to other lengths.

It is also possible to control the size of the light guide by shortening the optical length of the light guide in the x-direction. As shown in FIG. 7A, a light guide of optical length L1 may be cut at the cutting line 64. The resulting light guide with optical length Lx is shown in FIG. 7B. Even if a large amount of light leaks out at the end of the shortened light guide, this may be an economical way of creating light guides with different optical lengths.

8 shows an extended light guide. 8A is a plan view and FIG. 8B is a side view. The known light guide is extended by an extension 66. This extension 66 can guide light that is not out-coupled by the gratings to the required location of the display. In these locations, light may be out-coupled by out-coupling gratings 68. It may also be used to out-couple light for keypad illumination or decorative illumination.

As shown in FIGS. 8A and 8B, at the location of the diffractive out-coupling gratings 68, holes 70 are provided for the keys 71 that can activate the switch on the circuit board. The extension of the light guide substrate may also be used as a substrate for printed circuits. This is shown in FIG. The substrate on which the diffraction grating 25 is embossed may be used as a substrate for printed conductive lines 76, printed registers 74, capacitors (not shown), or even printed transistors (not shown). . Printing of electronic circuits onto a substrate is known and may be performed while the diffraction grating 25 is rolling.

The method according to the invention allows integrated mass production of light guides in which other foils are laminated and embossed with diffractive elements, in addition, in-coupling elements and through holes are provided, and the light guide is a backlight, or It may also be designed in accordance with the needs of the electronic device in which the frontlight is to be provided.

The list of reference numbers is as follows.

2; Foil 4; Rolling part 6; Bobbin

8; Optical film 10; Optical film 12; Bobbin

14; Bobbin 16; Laminate part 18; Light guide system

20; Laminate points 22; Laminate parts

24; Light guide segment 25; Diffraction gratings

26; Through-hole 27; Diffractive in-coupling element 28; LED

30; Flexible printed wiring board 32; LCD 34; connector

36; Ultraviolet (UV) -exposure 38; Phenomenon 40; Resulting structure

42a; Material deposition 42b; Etching 44; Deposited material

46; Lift-off 48; Final structure 50; Etched structure

52; Resistive layer 54 removed; Final structure 56; UV-light

58; Mask substrate 59; Mask 60; Photoresist layer

62; Substrate 64; Cutting line 66; Extended light guide

68; Diffraction out-coupling 70; Holes 71; Keys

72; Contact pads 74; Print register 76; Print Challenge Lines

Claims (42)

The light guide substrate is a foil, Diffraction gratings are embossed on one or both sides of the foil by rolling, And further optical films are provided continuously from the bobbin and laminated onto some side of the foil embossed after rolling. The method of claim 1, And the diffraction gratings are embossed into the foil in a continuous pattern. The method according to claim 1 or 2, Wherein said foil is provided continuously from a bobbin for rolling. The method according to claim 1 or 2, And further optical films are laminated onto some side of the foil embossed by heating or gluing. The method according to claim 1 or 2, And the optical films are laminated along the outer edges of the foil on some side of the foil. The method according to claim 1 or 2, And the optical films are laminated to corners of segments of the foil on some side of the foil. The method according to claim 1 or 2, Wherein said laminating comprises laminating additional optical films on one or both sides of said foil. The method according to claim 1 or 2, Light guide manufacturing method, characterized in that the first optical films are laminated on the first surface of the foil. The method of claim 8, And the first optical films are diffuser films and / or brightness enhancement films. The method of claim 8, And the second optical films are laminated on the second side of the foil. The method of claim 10, The second optical film is a light guide manufacturing method, characterized in that the reflector (reflector film). The method according to claim 1 or 2, And separating the foils by stamping or cutting to form individual light guides. The method of claim 12, Wherein said individual light guides are formed separately from said foil during lamination. The method according to claim 1 or 2, Diffractive in-coupling gratings are embossed into the foil by the rolling to provide in-coupling of light from the lighting elements illuminating at a constant angular distribution with respect to the surface of the foil into the foil. Light guide manufacturing method characterized in that. The method of claim 14, And at least one or more of the optical films at the positions of the diffractive in-coupling gratings to form through holes. The method of claim 12, Through holes are formed by cutting portions of each of the light guides at positions where the side light emitting illumination elements are positioned to enable in-coupling of light into the light guides by side firing lighting elements. Light guide manufacturing method characterized in that. The method according to claim 1 or 2, And the foil is rolled at a speed between 0.1 and 100 m / min. The method according to claim 1 or 2, The diffraction gratings are embossed by rotogravure, offset or flexo-printing. The method according to claim 1 or 2, The height of the diffraction grating is a light guide manufacturing method, characterized in that between 0.1 to 1 μm. The method according to claim 1 or 2, Any one or both of the foil and the optical films may be made of polycarbonate (PC), polymethylacrylate (PMMA), polyvinylchloride (PVC), polyethylene (PE), polyethylene tere Light guide manufacturing method comprising a phthalate (polyethyleneterephthalate, PET), or a thermoplastic (polyester) polyester (polyester) or a mixture thereof. The method according to claim 1 or 2, Any one or both of the foil and the optical film has a refractive index of between 1.3 and 1.8. The method according to claim 1 or 2, And the rolling temperature of the rolling is adjusted to emboss the gratings into the foil at a rolling speed. The method according to claim 1 or 2, The diffraction gratings are embossed on some side of the foil, Either or both of the electronic and opto-electronic components are printed on some side of the foil. The method of claim 23, wherein Either or both of the electronic and opto-electronic components are printed on the foil by either or both of an additional rolling process and an additional printing process. The method according to claim 1 or 2, And a portion of said foil is extended for use as a means of transmitting either or both optical signals and light to out-coupling elements. First supply means for providing a foil that is a light guide substrate; Rolling means for embossing diffraction gratings on one or both sides of the foil; Second and / or third supply means for providing additional optical films on one side of the foil; And Light laminating means for laminating said additional optical films on said embossed foil after rolling. The method of claim 26, Light guide manufacturing apparatus, characterized in that for continuously providing the foil using a bobbin. The method of claim 26 or 27, And after laminating said additional optical films to said foil, cutting individual light guides of said foil using cutting means. The method of claim 26 or 27, And after laminating the additional optical films on the foil, stamping individual light guides of the foil using stamping means. The method of claim 26 or 27, Said cutting means or said stamping means being integrated in said laminate means to split said foil during lamination. The method of claim 26 or 27, And said rolling means provides areas of diffraction grating patterns on said foil. In the manufacturing system of the light guide, First supply means for providing a foil that is a light guide substrate; Rolling means for embossing diffraction gratings on one or both sides of the foil; Second and / or third supply means for providing additional optical films on one side of the foil; And Light laminating means for laminating the additional optical films on the embossed foil after rolling. According to the method of claim 1, the light guide is produced by embossing diffraction gratings on one or both sides of the foil of the light guide substrate by rolling. The method of claim 33, wherein And one or both of the optical films laminated along the outer edges of the foil and the optical films laminated to the corners of the segments of the foil. The method of claim 33 or 34, Through holes in one or more of the additional optical films for in-coupling of light into the light guide from illumination elements illuminating at a constant angular distribution with respect to the surface of the foil into the foil. Light guide. The method of claim 33 or 34, Through holes formed by cutting any one or both of the foil and the films at positions where the lateral light emitting lighting elements are positioned to enable in-coupling of light into the light guide by the side light emitting lighting elements. Light guide comprising a. A mobile communication device comprising the light guide according to claim 33. delete delete delete delete delete

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