Title of Invention	LIGHTING DEVICE FOR SIGNALLING, DESIGNATING OR MARKING
Abstract	This invention relates to a Lighting device for signaling, designating or marking, comprising plurality of different light sources designed as semiconductor elements (1), for example light-emitting diodes (LEDs) or light-emitting polymers, characterized in that the lighting device has a control means (22) by means of which the intensity of the light emission of the semiconductor elements (1) is variable in a controlled fashion.

Title of Invention

LIGHTING DEVICE FOR SIGNALLING, DESIGNATING OR MARKING

Abstract

This invention relates to a Lighting device for signaling, designating or marking, comprising plurality of different light sources designed as semiconductor elements (1), for example light-emitting diodes (LEDs) or light-emitting polymers, characterized in that the lighting device has a control means (22) by means of which the intensity of the light emission of the semiconductor elements (1) is variable in a controlled fashion.

Full Text	1A The invention relates to a lighting device for signalling, designating or marking, having light sources which are designed as semiconductor elements, for example as light-emitting diodes (LEDs) or as light-emitting polymers. It is possible by means of such semiconductor elements for light to be emitted from a lighting device outlined above in a prescribed colour, without there being a need for any sort of optical radiation filtering. Accordingly, such a semiconductor element scarcely generates radiation outside the visible region, in particular scarcely generates heat-generating infrared radiation or ultraviolet radiation. The outlay on power for operating such a semiconductor element or a lighting device having such semiconductor elements is thus low. It is the object of the invention to make available, starting from the prior art outlined above, a lighting device whose light emission can be adapted in a simple way to different requirements and to different light conditions. This object is achieved according to the invention owing to the fact that the lighting device has a control device by means of which the intensity of the light emission of the semiconductor elements is variable in a controlled fashion. As a result, the light emission of the lighting device can be adapted to the most different conditions by varying the intensity with which the semiconductor elements emit light. Since, even when their light emission is controlled with regard to intensity, such semiconductor elements emit light with a range of wavelengths which is very narrow and constant, the colour of the light emitted from the lighting device is the same for a different intensity of- the emitted light. -Adapting the light emission of the semiconductor elements to changes prescribed by the control device is performed in - 2 - microseconds, as a result of which the lighting device according to the invention can also satisfy strict requirements. If the lighting device according to the invention has different semiconductor elements for emitting light in different colours, it being possible for the emitted light of different semiconductor elements to be mixed arbitrarily, the light emitted from the lighting device can be set arbitrarily with regard to colour and/or intensity. It is therefore possible to use one and the same lighting device to emit light of different col-our. The efficiency of such a lighting device can be increased by virtue of the fact that the semiconductor elements emit their light with a very narrow colour bandwidth and at a very high saturation. Since the colour of the emitted light does not change perceptibly with control of the intensity; the colour setting can be selected with respect to the efficiency. Using a lighting device according to the invention configured in such a way, light can be emitted virtually in the entire visible colour range, all colours which can be used sensibly in a technical way being possible. This does not require any mechanical movement of lamps, filters or other parts to be moved physically; the corresponding properties of the lighting device according to the invention follow from static, controlled components. The addition of colours which are generated by individual semiconductor elements means that the light visible to the human eye can be of any colour, since it is no longer possible to resolve the light of different semiconductor elements after two arc minutes corresponding to a distance of 0.5 m from the lighting device. The lighting device can expediently be dimmed and/or switched by means of the Control device) serving to control the power supply.. When this control device has an electronic light controller, the sensitivity of the semiconductor elements can be adapted to the customary sensitivity of incandescent lamps and tungsten-arc lamps, so that the light- - 3 - ing device according to the invention can be combined in the same system with conventional lighting devices having tungsten-arc lamps and incandescent lamps. The control device can be connected for signalling purposes to a central unit by a power supply line and/or a separate electric or optical data line. The control device can serve to control the intensity of emission of the semiconductor elements. Moreover, it can be prescribed by means of the control device in which of several possible directions light is emitted, if the lighting device is designed as a bidirectional or omnidirectional lighting device. By means of this control device the intensity of emission and the number of the semiconductor elements emitting light of different colour can be set so that the lighting device can be used to emit light of any desired colour at any desired intensity. Moreover, the control device can set a specific succession of OFF and, if appropriate different, ON operating states. Of course, it is possible in accordance with an advantageous embodiment of the lighting device according to the invention to use the control device to monitor the operating state and the operability of the semiconductor elements functioning as light source. When the lighting device according to the invention has semiconductor elements which emit red, green or blue light and are arranged alternately, it is possible in particular for the variable white light which is particularly important in operating an airport to be emitted in any desired form. As a result, the lighting device can be adapted in an optimum way to different climatic conditions, it naturally being possible, in addition, to take account of different lighting conditions as well. Since red, blue and green are arranged at the outer corners of a colour triangle, and the lighting device can have a desired number of corresponding semiconductor elements, this lighting device can be used to generate all the colours. Moreover, the lighting device - 4 - according to the invention can be used immediately to fulfil the requirements with regard to light propagation. If the aim is to use the lighting device according to the invention to emit only red, yellow, orange and green light, it is sufficient if it has semiconductor elements which emit red or green light and are arranged alternately. Semiconductor elements emitting blue light are not required in this case, since they are not important for the emission of light in the abovementioned colours. If light is to be generated only in the said four colours, specifically red, yellow, orange and green, the result of dispensing with semiconductor elements emitting blue light is that the lighting device according to the invention can be configured with smaller dimensions in conjunction with the same possible light intensity. It is possible to arrange mutually juxtaposed rows of semiconductor elements of a cluster offset relative to one another, resulting in some circumstances in a denser population of a substrate with semiconductor elements. If the control device of the lighting device according to the invention has a pulse-width modulation device by means of which the electrical power fed to the semiconductor elements can be controlled, the result is a high efficiency for operating the lighting device according to the invention, it being possible for the power rendered available to be adapted in an optimum way to the requirements of the lighting device or the requirements of the semiconductor elements by means of the pulse-width modulation device. There is, no need for a thyristor- controlled power supply which, in its turn, would typically cause harmonization and reactive losses in the main source. Moreover, the operation of the lighting device according to the invention produces no stroboscopic effect which could impair the correct perception of the lighting device. It is possible for a plurality of semiconductor elements of the lighting device to form a cluster, it - 5 - being possible for 2 to 200, preferably 2 to 30, semiconductor elements to belong to a cluster. The failure of semiconductor elements can be compensated thereby, since a cluster having a plurality of semiconductor elements remains operable even when one or more semiconductor elements fail. In an advantageous embodiment, the lighting device according to the invention can be designed as a cluster arrangement of a plurality of individual clusters, for example, of 1 to 30, preferably 1 to 16. The spatial light distribution of the lighting device can thereby be optimized in accordance with the prescribed requirements. The global photometric properties of the lighting device are determined by the cluster arrangement . In an advantageous embodiment of the lighting device according to the invention, the semiconductor elements of a cluster, which are preferably designed without a mounting, are arranged on a common substrate. When the substrate holding the semiconductor elements is provided on its side facing the semiconductor elements with a layer made from a reflecting material, it is ensured that the radiation components of the semiconductor elements which are not directed towards the radiation-emitting surface of the cluster or of the lighting device are deflected there as far as possible. In accordance with one embodiment of the lighting device according to the invention, in which there is arranged on the output side of the semiconductor elements a mirror surface by means of which the direction of emission of the semiconductor elements is deflected, the direction of emission of the lighting device can be provided virtually as desired, depending on the positioning of the mirror surface. When the dimensions of the radiation-emitting surface of the lighting device correspond approximately to the area of the substrate holding the semiconductor elements, the result is an emission of light from the lighting device which is uniform and thus perceived as - 6 - pleasant. When the lighting device according to the invention can be assembled in a modular fashion from possibly different clusters and/or cluster arrangements, it is possible to fit such a lighting device together without great outlay for virtually any conceivable use and any conceivable requirements. Thus, for example, a lighting device, which is of bidirectional design and has two cluster arrangements of which each emits in a direction opposite to that of the other, can be used at an airport to indicate the centre line of a straight taxiway, and also as a stop light; if the lighting device has two cluster arrangements which emit light in directions inclined to one another, they can be used on curved sections of taxiways to indicate the centre line thereof, or as a stop-light. When the cluster arrangements of this lighting device have a plurality of, for example three or five, clusters arranged next to one another, mutually juxtaposed clusters respectively enclosing an angle of less than 180 degrees, it is possible to optimize the spatial distribution of the light emitted from the lighting device. If the lighting device is intended to be of omnidirectional design, it is advantageous when its cluster arrangements are of curved design and form a circle or the lateral surface of a cylinder. If the lighting device is to emit light in two directions, it is advantageous when the semiconductor elements are arranged in rows or in columns. If the lighting device is to emit light omnidirectionally, an arrangement of the semiconductor elements in circles or cylinders is advantageous. However, other arrangements of the semiconductor elements are also possible. Owing to the reflecting configuration of the side of the substrate facing the semiconductor elements, it is possible to provide an elementary optical system in cooperation with the radiation-emitting sections of the semiconductor elements themselves, if the emitting - 7 - sections of the semiconductor elements have the form of an aspherical lens. The use and the distribution of the generated light can hereby be of optimum configuration. The semiconductor elements of the lighting device according to the invention can be constructed from an inorganic or organic material, in particular from plastic. This yields substantial advantages with regard to weight and to the possibilities of production. Moreover, the individual clusters can be cast or injected from a plastic, it being possible to use a recyclable plastic as plastic. It is possible to select a material which is a good conductor of heat for the individual clusters, it also being possible to use a pressure-resistant plastic. If the clusters form a compact unit with a housing of the lighting device, this dispenses with any sort of hollow convection space. When there is arranged in front of the semiconductor elements of the lighting device according to the invention a cover plate by means of which the beams emitted from the semiconductor elements can be influenced optically, it is possible to improve the emission of light from the lighting device, for example by focusing and aligning the beams. The semiconductor elements can be assigned an optical device for beam refraction and/or total reflection, it being possible to provide a high-performance optical system by means of which the light emission can be optimally formed so that it satisfies in any case the requirements, already mentioned at the beginning, occurring in airport operation. If the outside of the cover plate is easy to clean and is hardened, the outlay on maintenance for the lighting device can be reduced. The outside of the cover plate should expediently be of self-cleaning design, it being possible for the cover plate to be coated in a suitable way. A compact configuration of the lighting device can be achieved when the semiconductor elements are - 8 - arranged embedded in a filler member. If the filler member embedding the semiconductor elements has a cutout on the active surface or the light-emitting opening of the semiconductor elements, it is possible to maintain the use of the previously explained elementary optical system, to which the reflecting configuration of the side of the substrate facing the semiconductor elements and the aspherical lens on the emitting section of the semiconductor elements belong. In accordance with an advantageous embodiment of the lighting device according to the invention, the filler member is constructed from a transparent material, for example a transparent resin, in particular epoxy resin, whose refractive index approximately corresponds to that of the cover plate. Optical losses on the transition surface between the filler body and the cover plate are hereby eliminated. The individual semiconductor elements are expediently constructed such that they can be manipulated in a fully or partly automatic fashion. The clusters of the lighting device according to the invention are expediently components of a redundantly operating system, with the result that it is possible in any case reliably to prevent a total failure of the lighting device according to the invention. Since, because of the redundant configuration of the system formed by the clusters, not every failure of an individual semiconductor element need necessarily lead to the exchange of a cluster, the outlay on maintaining the lighting device according to the invention can be further reduced. In order further to simplify the assembly, the modification or the repair of the lighting device according to the invention, it is advantageous when one or more clusters of the lighting device is or are designed as an exchangeable subunit, in particular as a cassette. It is then possible for a cassette belonging to the lighting device to be exchanged in situ. Such a cassette is advantageously type coded, so - 9 - that it can be installed in the lighting device exclusively in accordance with its arrangement prescribed in the lighting device; as a result, it is virtually impossible to make errors when replacing such cassettes in situ. In an advantageous embodiment, it is possible for the purpose of realizing this type coding for there to be constructed on the outside of the cassette projections or depressions which are assigned to depressions or projections, respectively, on the holder of the lighting device which holds the cassette. In the case of the cassette and in the case of the holder on the side of the lighting device, such projections or depressions can contribute to their reinforcement and capacity to resist shear stresses. Loads and stresses introduced onto the cassette can be transferred by means of the holder onto the roadway, it being possible for these to be both mechanical, specifically static and dynamic loads, and thermal loads resulting from the requirement for thermal dissipation. For the purpose of connecting the cassette, a mounting for electrical contacts which is sealed off against the environment is provided on the holder; in order to connect the cassette in the desired way to a power supply, the holder can also have a part for power supply and control. When the basic body or the housing of the cassette is filled entirely or partly with an electrically non-conducting material, for example resin or plastic,, electrical corrosion can be avoided. If a non-conducting filler, for example glass, is added to the electrically non-conducting material, the thermal capacity for dissipation and load carrying of the cassette can be increased. The thermal resistance between the clusters present in the cassette is lowered, with the result that the transfer of heat between the clusters and the basic body or the housing of the cassette is based on thermal conduction instead of convection. Since there are no cavities inside the cassette, the cassette is inherently watertight and gastight. - 10 - If the walls, in particular a bottom wall of the basic body or of the housing of the cassette, are or is designed as thermal conductors, for example, made from stainless steel or aluminium, the temperature gradient inside the cassette can be reduced. The outside of the cassette is advantageously provided with a hardening, at least on the main stress regions; as a result, damage owing to abrasion, scratches or point loads can be avoided to a very great extent. Moreover, such a reinforcement, in particular at the fastening points of the cassette, can have the effect that the load stresses and shear stresses can be better distributed on the holding part of the lighting device. Externally exposed surfaces of the cassette or of the entire lighting device can be hardened by means of sapphire or appropriate glass, so as to avoid a degradation of the efficiency of the lighting device owing to abrasion, or physical or chemical damage. As already set forth above at the appropriate juncture, the lighting device according to the invention can be provided for signalling on as well as designating and marking traffic areas in airports, for example runways, taxiways and the like. It can be designed straight away in accordance with the standards valid in air traffic and for airports, for example ICAO, FAA, DOT, CIE, MIL-C-25050. In one configuration of the lighting device as a flush-marker light, the absence of cavities ensures that, when driven over by a vehicle or an aircraft, the lighting device or the cassettes forming it are not exposed to bending stresses, but exclusively to compressive stresses. Since in the case of a lighting device configured in this way as a flush-marker light the rise in temperature owing to the operation of the light sources is less than 2 0% of the rise in temperature in the case of conventional lighting devices, the stresses from the aircraft tyres crossing the flush-marker light' can be substantially reduced. Moreover, the risk of burns can be substantially excluded for operating personnel. -li- It is also possible to configure the lighting device according to the invention such that it can be used to designate and mark traffic areas in road traffic, for example for roadway direction displays, roadway lane markings, speed restriction displays and the like. Moreover, it is also possible to consider a configuration of the lighting device according to the invention for operating in navigation, for example for beacon lights, navigation channel displays, buoy markings and the like. In accordance with an advantageous configuration of the invention, the basic body or the housing of the lighting device is constructed from a metallic and electrically non-conducting material. The use of such materials for lighting devices in airports has not so far been practicable, since the tungsten-arc lamps and incandescent lamps used as light sources have generated excessively high temperatures. Since the metallic and electrically non-conducting materials which can be used in the case of the invention are electrically isolating, no electrical corrosion occurs in the case of the light-ing device according to the invention. The material provided in the case of the lighting device according to the invention can be formed into virtually any shape with a low outlay. It can, moreover, serve as a thermal conductor, in order to dissipate the heat generated by the lighting device to the mounting part holding the lighting device, or to the roadway. Since the entire basic body or the entire housing of the lighting device according to the invention can be designed as an insulator by selecting the material which can now be used, no costly separate insulator is required. A recyclable plastic can be used for the basic body or the housing of the lighting device, the outcome being the ecological advantages resulting therefrom. Since the materials which can now be used to configure the lighting device according to the invention have a substantially longer lifetime by comparison with the prior art, the use cycles of the lighting device according to the invention are correspon- - 12 - dingly lengthened. The semiconductor elements of the lighting device according to the invention can be controlled electrically between very low and very high potentials, the range of wavelengths of the emitted radiation being very narrow over the entire control range and entirely constant with regard to position and width, with the result that light of one and the same colour can be emitted over the entire control range. The invention is explained in more detail below with the aid of exemplary embodiments and with reference to the accompanying drawing, the application of the invention in the field of airports, in particular, being described. Figure 1 shows a representation of the principle of a semiconductor element designed as a light-emitting diode; Figures 2 to 4 show, in front, side and top views, the principle of a first embodiment of a cluster of a lighting device according to the invention; Figures 5 to 7 show, in front, side and top views, the principle of a second embodiment of a cluster of the lighting device according to the invention; Figure 8 shows a top view of a first exemplary embodiment of the lighting device according to the invention; Figure 9 shows a top view of a second exemplary embodiment of the lighting device according to the invention; Figure 10 shows a top view of a third exemplary embodiment of the lighting device according to the invention; Figure 11 shows a sectional representation of the exemplary embodiment, represented in Figure 8 for example, of the lighting device according to the invention; Figure 12 shows a representation corresponding to Figure 11, the lighting device being constructed from clusters in accordance with Figures 5 to 7; Figure 13 shows a further embodiment of the - 13 - lighting device according to the invention; Figures 14 to 17 show representations of the principle of clusters having different semiconductor elements; Figure 18 shows a representation of the fixed colours provided for airport lighting systems; Figure 19 shows a representation of the principle of the control, regulation and monitoring of airport lighting systems; Figure 20 shows a representation of the principle of the output side of a pulse-width modulation device of the lighting device according to the invention; Figure 21 shows a control device of the lighting device according to the invention; and Figure 22 shows a modified control device of the lighting device according to the invention. A lighting device according to the invention has a multiplicity of semiconductor elements which are designed in the case of the embodiments described below as light-emitting diodes 1. The light-emitting diode 1 represented in principle in Figure 1 has, in that region in which the light generated emerges from the diode 1, a configuration as an aspherical lens 2, as is represented, in particular, in Figure 1. Owing to the aspherical configuration of the light-refracting lens 2, the distribution of the light emitted by the diode 1 can be optimized. The light-emitting diode 1 is, in particular, a bright or superbright LED. The lighting device according to the invention is assembled from a multiplicity of previously described light-emitting diodes 1. A plurality of such light-emitting diodes 1 can be combined to form a cluster 3 represented in Figures 2 to 4. In the exemplary embodiment represented in Figures 2 to 4, the cluster 3 has ten light-emitting diodes 1, which are arranged in two rows, of five light-emitting diodes 1 each, arranged one above another. It is possible for the centre lines of the diodes - 14 - 1 of a row to be arranged inclined with respect to the centre lines of the diodes 1 of a neighbouring row. All the light-emitting diodes 1 of this cluster 3 are arranged without a mounting on a substrate 4 which serves as a holder for the light-emitting diodes 1. The cluster 3 has an elementary optical system, to which there belongs a reflecting layer 5 which is applied to the side of the substrate 4 facing the light-emitting diodes 1. The aspherical lenses 2 of the light-emitting diodes 1, which optimize the use and distribution of the light generated by the light-emitting diodes 1, belong to this elementary optical system. The aspherical lens 2 respectively forms the actual active surface or the light-emitting opening of the light-emitting diodes 1. The cluster 3 represented in Figures 2 to 4 is configured as a module part which can be assembled with other identical or similar clusters 3. On the light-emitting surface 6, the cluster 3 is closed by means of a cover plate 7 which, in the case of the cluster 3 represented in Figures 2 to 4, is arranged parallel to the substrate 4. With regard to its dimensions, the radiation-emitting surface 6 of the cluster 3 corresponds essentially to the surface of the substrate 4, which is virtually completely covered by the light-emitting diodes 1. The light-emitting diodes 1 of the cluster 3 are surrounded by a filler member 8 which fills up the space between the substrate 4 and the cover plate 7 and is produced from a transparent material, for example from a resin. The filler member 8 has a cutout 9 which is assigned directly to the emitting section of the cluster 3 formed by the aspherical lenses 2 of the light-emitting diodes 1 of the cluster 3; the cutout 9 is constructed between the active surface of the light-emitting diodes 1 of the cluster 3 and the filler member 8, in order not to lose use of the elementary optical system formed by the reflecting layer 5 of the substrate 4 and the aspher-ical lenses 2 of the light-emitting diodes 1. The refractive index of the material forming the - 15 - filler member 8 expediently corresponds to that of the material forming the cover plate 7. As a result, optical losses at the contact surface between the filler member 8 and the cover plate 7 can be prevented. The outside of the cover plate 7 of the cluster 3 is of hardened and smooth configuration; it can, moreover, be self-cleaning. In the embodiment of the cluster 3, as it is represented in Figures 2 to 4, the direction of emission, represented by the arrow in Figure 3, of the cluster 3 is arranged perpendicular to the plane of the substrate 4. In the embodiment, represented by Figures 5 to 7, of the cluster 3, the direction of emission, represented by the arrow in Figure 6, of the cluster 3 is deflected by 90 degrees, for which purpose a mirror surface 10 is provided which is arranged between the light-emitting diodes 1 and the radiation-emitting surface 6 of the cluster 3. The mirror surface 10 resets the light beams by 90 degrees in the exemplary embodiment represented, with the result that they emerge parallel to the plane of the substrate 4 from the cluster 3 through the light-emitting surface 6 thereof or through the cover plate 7 thereof. A taxiway centre and stop light for a straight section of a taxiway is represented in Figure 8. What is involved in this case is a so-called bidirectional lighting device, having a first cluster arrangement 11, which emits in the direction marked by the arrow 13, and a second cluster arrangement 12, which emits in the direction opposite to that of the cluster arrangement 11 and marked by the arrow 14. The lighting device represented in Figure 8 is a compact device, the two cluster arrangements 11, 12 being arranged in a common housing 15. That region of the interior of the housing 15 which is arranged between the two cluster arrangements 11, 12 as well as, in Figure 8, to the side of the two cluster arrangements 11, 12 is filled with a suitable material. The housing 15 can be of metal construction. - 16 - Apart from the fact that they emit in different directions, the cluster arrangements 11, 12 correspond to one another, and so only the cluster arrangement 11 on the right in Figure 8 is described in detail below. The cluster arrangement 11 has three clusters 3, which are arranged in a row next to one another, it being possible for each of these clusters 3 to have, for example, the embodiment represented by Figures 2 to 4. The middle cluster 3 is arranged at right angles to the centre line 16 of the taxiway, intersecting this centre line 16 in its middle region. The two outer clusters 3 respectively enclose with the middle cluster 3 an angle which is slightly less than 180 degrees. An efficient horizontal light distribution is achieved hereby. The cover of the lighting device represented in Figure 8 has a hardened, smooth outer surface which is thereby configured such that it can be cleaned in a simple way. The lighting device represented in Figure 9 likewise serves for marking the centre line of a taxiway, but on a curved section thereof, and as a stop light which can be used there. It differs from the lighting device represented in Figure 8 by virtue of the fact that the directions of emission of the two cluster arrangements 11, 12 are inclined to one another, and that there are provided per cluster arrangement 11, 12 five indi -vidual clusters 3, which can likewise be such as the embodiments represented in Figures 2 to 4 . Since a curved section of the taxiway is involved, the middle cluster 3 of the two cluster arrangements 11, 12 is offset and inclined to the centre line CL of the lighting device. The clusters 3 of the two cluster arrangements 11, 12 likewise enclose with the respectively adjacent cluster 3 an angle alpha which is less than 180 degrees. Figure 10 shows a lighting device which acts in all directions and can likewise be provided for marking a taxiway. Six curved clusters 17, which form a closed circle with one another and are separated from one another by structural ribs 18, are provided in the embodiment represented. Light can be emitted virtually in - 17 - all directions by means of the six curved clusters 17. In the lighting devices described above with the aid of Figures 8 to 10, the outer optical surface can be of transparent and hard configuration, for example made from sapphire or glass with a hardened surface, so that a degradation of the efficiency of the lighting devices because of abrasion and physical or chemical damage is avoided. The outer optical surface can be hardened or coated in such a way that any possible Fresnel losses are reduced. Represented in Figures 11 and 12 are cross-sections through lighting devices, which correspond, for example, to the lighting devices represented in Figures 8 to 10, and are designed as flush-marker lights. They differ from one another essentially in that, in Figure 11, the clusters 3 of the embodiment described with the aid of Figures 2 to 4 are used, whereas in the case of the flush-marker light in accordance with Figure 12 use is made of clusters of the embodiment explained with the aid of Figures 5 to 7. The lighting device in accordance with Figures 11 and 12 is arranged with substantial parts below ground level 19. The arrows represented in Figures 11 and 12 mark the directions of emission of the flush-marker lights. As follows, in particular, from Figure 11, the part of the flush-marker light having the cluster or clusters 3 is configured in the form of a cassette 2 0 which, as such, forms a unit which can be exchanged without a high outlay. Such a flush-marker light can have one or more such cassettes 20. Depending on the configuration of the lighting device, a plurality of identical or, possibly, also different cassettes can be assembled to form the lighting device. In an advantageous embodiment, such a cassette 2 0 is type coded, the type coding corresponding to its arrangement inside the lighting device. As a result of this, errors are rendered virtually impossible during an in situ replacement of the cassette 20. The type coding can be implemented by projections or cutouts on the - 18 - cassette side, corresponding cutouts or projections then being provided in a holding part 21 of the lighting device. Such relief-type configurations of the cassette 20 and of the holding part 21, or configurations provided with indentations can, moreover, contribute to the capacity to withstand shear stresses. The basic body or the housing of the cassette 2 0 is filled entirely or partially with an electrically non-conducting material, for example a resin or plastic; electrical corrosion is avoided hereby. A thermally conducting material, for example glass, can be added to the non-conducting material, in order thus to increase the capacity of the cassette 20 for thermal dissipation and its capacity for accepting loads. The thermal transmission between the clusters 3 and the basic body or the housing of the cassette 2 0 is then based on thermal conduction instead of air/gas convection, with the result that the thermal resistance of the cassette 2 0 is substantially reduced. Since no convection gas is present, any possible aircraft or vehicle loads which act on the cassette 20 do not lead to bending stresses, but exclusively to compressive stresses, which can be absorbed or dissipated more easily. The cassette 20 is inherently watertight and gastight, because there are no cavities, and thus no convection gas, inside the cassette 20. The rise in temperature occurring in the cassette 20 is only less than 20% of the rise in temperature in the case of a lighting device with a conventional tungsten-arc light source, with the result that aircraft or vehicle tyres are by far less stressed, and burning of operating and maintenance staff can be excluded. The bottom wall of the cassette 20 can be constructed by a thermal conductor, for example stainless steel or coated aluminium; the temperature gradient inside the cassette 20 is reduced hereby. The outside of the cassette 20 can be constructed in a hardened fashion, for example from a stainless - 19 - steel, thus avoiding damage owing to abrasion, scratches or point loads. Fastening points of the cassette 20 can be of reinforced design, so that load and shear stresses on the structure supporting the cassette 2 0 or on the holding part 20 can be distributed more effectively. The introduction of power or the transmission of signals into the cassette 2 0 is accomplished by self -cleaning and self-sealing contacts. Watertight and vapourtight protection against the environment is provided. Because of the design of the lighting device with light-emitting diodes 1, the transmission of electrical power between the cassette 2 0 and the remaining parts of the lighting device is performed at a very low voltage level, with the result that it is possible to carry out a "hot" cassette replacement without the danger of damaging the electrical contacts and without the risk of electric shock to the staff; in this case, the voltage level is below a peak voltage of approximately 25 V. The cassette 20 is arranged above a power supply and control device 22 of the lighting device. Since the cassette 20 is constructed as far as possible without cavities, it resists mechanical stresses of 100 G and vibrational stresses of up to 30 G, it being unimportant whether the lighting device is energized or not energized. Loads and stresses introduced onto the cassette 20 are transferred onto the roadway by means of the holding part 21. These stresses are static and dynamic mechanical loads as well as thermal loads which arise from the need to dissipate the heat produced. Figure 13 shows an embodiment of the lighting device which is arranged in a conventional way above a roadway. There, too, a cassette 20 configured to be capable of exchange in a modular fashion is arranged above a power supply and control device 22, the power supply and control device 22 being arranged above the ground level 19 with the aid of a detachable coupling 23. - 20 - Figure 14 shows a representation of the principle of a cluster 3 which is assembled from red, green and blue light-emitting diodes l. In a way still to be described, the intensity with which the light-emitting diodes 1 emit light of each colour can be controlled. Owing to the fact that the light-emitting diodes 1 of each of the three colours can emit light at the respectively desired intensity, light can be emitted virtually in all visible colours by means of the cluster 3 shown in Figure 14, it being possible, moreover, for this light to be emitted at different intensities. As follows, in par-ticular, in conjunction with Figure 18, the colours of red, green and blue provide the possibility of emitting light of any intensity and in any colour conceivable for possible signals. Such a configuration of a cluster 3 can also be used to emit white light at different intensities, something which is difficult with conventional lighting devices. The reason for this is that red, green and blue are arranged in the colour spectrum approximately at the corners of a triangle which describes the visible colour range, as follows from Figure 18. The light emerging from the cluster 3 can no longer be differentiated into individual light sources at a distance of two arc minutes corresponding to an observing distance of 10 m, with the result that light can be produced in the desired colour and intensity for all purposes. This also holds, in particular, for the standards ICAO, FAA, DOT, CIE, MIL-C-25050 valid in aviation. A cluster 3 which, as already mentioned, contains light-emitting diodes 1 whose light is red, blue or green is best suited for generating variable white light. As already mentioned, these three colours are arranged at the outer corners of a triangle which is to be seen in Figure 18 and corresponds to the said standards. Only four colours, specifically red (R), yellow (Y) , orange and green (G) are required to mark taxiway markings and route information. It is simpler and less expensive for such an application when a cluster 3 - 21 - contains only two different types of light-emitting diodes 1, specifically ones which emit red light, and ones which emit green light. Such a cluster 3 is represented in principle in Figure 15. Diodes 1 emitting blue light can be dispensed with in this case. The clusters 3 in accordance with Figure 16 and Figure 17 differ from the clusters 3 represented in Figure 14 and Figure 15 only by virtue of the fact that the individual light-emitting diodes 1 are not arranged in rows offset relative to one another; in the case of the clusters 3 in accordance with Figures 16 and 17, the light-emitting diodes 1 arranged below or above one another are not offset relative to one another. Light-emitting diodes 1 are available on the market from different manufacturers and in different colours. Thus, for example, the Toshiba company manufactures LEDs for emitting light in red, orange and yellow colours; the Hewlett-Packard company manufactures diodes for emitting light in amber, orange, red-orange and red colours; the Ledtronics company manufactures diodes for emitting light in green, yellow, orange, red and blue colours. The supply of power to the light-emitting diodes 1 is controlled with minimum losses by a pulse-width modulation device 24, the peak current being set in an initialization method by means of which the type of the light-emitting diode is identified in accordance with the result of a comparison of the voltage drop across a chain of light-emitting diodes with the voltage drop across a reference LED. The control or inclusion and integration of the lighting devices according to the invention into a control system of an airport will now be explained with the aid of Figure 19. An air traffic control centre 25, an emergency control centre 26 and a maintenance control centre 27 are connected in a suitable way to a controller 28 for routes and gates. This controller 28 is connected, in turn, to substations 29, 30, 31, of which only the substation 29 - 22 - is represented in detail in Figure 19. It may be pointed out that a star-shaped connec-tion between the controller 2 8 and the substations 29, 30, 31 is represented in Figure 19, but that it is also possible in principle to provide a loop connection or a bus connection. The substation 29 has a subcontrol device 32 with a panel 33. Via a CCR 34 and a master circuit 35 in each case, the actual control devices 22 of the lighting devices according to the invention are connected to the subcontrol device 32. The already mentioned pulse-width modulation device 24 belongs to the control device 22, which is represented in detail in Figures 21 and 22. The output power of the said pulse-width modulation device 24 can vary, as emerges from Figure 20, whose upper part represents an output power of the pulse-width modulation device 24 with a low intensity, and whose lower part represents an output power of the pulse-width modulation device 24 with a high intensity. The control devices 22 represented in Figures 21 and 22 differ from one another only in that the control device 22 represented in Figure 21 has no separate data line 36, but has only a power supply line 37, which also serves the purpose of data transmission. The control device 22 includes a power adapting and sensor unit 38 which is__connected to the pulse-width modulation device 24 and a controller 39. The pulse-width modulation device 24 is likewise connected to the controller 3 9 and an outlet sensor 40, which is likewise connected to the controller 3 9 and via which the light-emitting diodes 1 of the lighting device are driven. The controller 39 is connected to the power supply line 37 or the data line 36 via a modem 41 and a connecting circuit 42. A unit of the Intel 8051 type can be used as the controller 39. A PC can be used as the substation control device 32, a SICOMP-PC being a possibility. The control of the lighting device includes the - 23 - regulation of the intensity of emission of the diodes 1, the selection of that direction or those directions in which light is to be emitted from the lighting device, the selection of the colour in which light is to be emitted, the light flash coding or the time sequence of light pulses, ON and/or OFF operation controlled as a function of time, monitoring of the diodes 1, and auto-matic "power on default start-up" selection and an automatic "fallback default" selection in the event of control failure. Further optional features are possible. The input power incoming at the control device 22 is automatically detected and adapted to the requirements of the lighting device. In the case of a standard constant-current series circuit input power, the output power of the pulse-width modulation device 24 is adapted such that the exponential response typical of tungsten-arc lamps or incandescent lamps is produced, with the result that the lighting device according to the invention can be combined with conventional lighting devices in one and the same circuit . The modem 42 codes the modulated control signals from the power supply line 37 or the data line 36 and assigns the control signals. The modem 41 alternately modulates and codes monitoring signals which come from the Lighting device, in order to make these available to a central control and monitoring system. The modem 41 operates in two directions, in order to be able to transmit the control and monitoring signals in a suitable way. A component of the control device 22 is a moni-toring part by means of which the lighting device is monitored for line interruption, earth fault, supply lead faults and the like. The clusters 3 can, for example, also be moni-tored for operability by means of a selenium cell. 24 We Claim: 1. Flush-marker light for signaling on and identifying traffic areas, having light sources designed as semiconductor elements (1), for example as light-emitting diodes (LEDs) or as light-emitting polymers, different semiconductor elements (1) being provided in the form of clusters which in each case emit light of different colours, characterized in that the flush-marker light is suitably designed as an airport flush-marker light which can be rolled over by aircraft and is intended for lighting take-off runways, landing runways, taxiways and the like and has a control device (22) with a pulse-width-modulation device (24) by means of which the electrical energy fed to the semiconductor elements (1) can be regulated and the intensity of the light emission of the semiconductor elements (1) can thereby be varied in a controlled fashion. 2. Flush-marker light as claimed in claim 1, wherein the emitted light of different semiconductor elements (1) can be mixed at will by means of the control device (22). 3. Flush-marker light as claimed in claim 1 or 2, which can be switched by means of its control device (22) which serves the purpose of control and power supply. 4. Flush-marker light as claimed in one of claims 1 to 3, whose control device (22) has an electronic light regulator. 5. Flush-marker light as claimed in one of claims 1 to 4, whose control device (22) is connected for signaling purposes to a central unit by means of a power supply line (37) and /or a separate electric or optical data line (36). 5. 25 6. Flush-marker light as claimed in one of claims 1 to 5, by means of which the light can be emitted in a plurality of directions, and by means of whose control device (22) it is possible to select the direction of emission or the directions of emission. 7. Flush-marker light as claimed in one of claims 1 to 6, by means of whose control device (22) the intensity of emission and the number of the semiconductor elements (1) emitting light of different colour can be set such that light of arbitrary colour can be emitted with arbitrary intensity by means of the flush-marker light. 8. Flush-marker light as claimed in one of claims 1 to 7, by means of whose control device (22) it is possible to set a specific sequence of off and different on operating states. 9. Flush-marker light as claimed in one of claims 1 to 8, by means of whose control device (22) the operating state and the serviceability of the conductor elements (1) can be monitored. l0. Flush-marker light as claimed in one of claims 1 to 9, which has semiconductor elements (1) which emit red, green and blue light and are arranged alternately. 11.Flush-marker light as claimed in one of claims 1 to 9, which has semiconductor elements (1) which emit red and green light and are arranged alternately. 12. Flush-marker light as claimed in one of claims 1 to 11, wherein mutually adjacent semiconductor element rows are arranged offset from one another. 13.Flush-marker light as claimed in one of claims 1 to 12, wherein 2 to 200, preferably 2 to 30, semiconductor elements (1) form a cluster (3). 26 14. Flush-marker light as claimed in one of claims 1 to 13 which is designed as a cluster arrangement made from a plurality of individual clusters (3). 15. Flush-marker light as claimed in claim 14, wherein l to 30, preferably 1 to 16, clusters (3) form a cluster arrangement ( 11, 12). 16. Flush-marker light as claimed in one of claims 1 to 15, wherein the semiconductor elements (1) of a cluster (3) are arranged on a common substrate (4). 17. Flush-marker light as claimed in one of claims 1 to 16, whose individual semiconductor elements (1) are designed without holders. 18.Flush-marker light as claimed in claim 16 or 17, wherein the substrate (4) holding the semiconductor elements (1) is provided on its side facing the semiconductor elements (1) with a layer (5) made from a reflecting material. 19. Flush-marker light as claimed in one of claims 1 to 18, wherein there is arranged on the output side of the semiconductor elements (1) a mirror surface (10) by means of which the direction of emission of the semiconductor elements (1) is deflected. 20. Flush-marker light as claimed in one of claims 16 to 19, the dimensions of whose radiation exit surface (6) correspond approximately to the area of the substrate(4) holding the semiconductor elements (1). 20. 27 21.Flush-marker light as claimed in one of claims 1 to 20, which is of bi-directional design and has two cluster arrangements (11, 12) of which each emits light in a direction opposite to that of the other. 22. Flush-marker light as claimed in one of claims 1 to 20, which is of bi-directional design and has two cluster arrangements( 11, 12) which emit light in mutually inclined directions. 23. Flush-marker light as claimed in claim 21 or 22, wherein each cluster arrangement (11, 12) has a plurality of , for example three or five, clusters (3) arranged next to one another, mutually adjacent clusters (3) enclosing an angle of less than 180degrees in each case. 24. Flush-marker light as claimed in one of claims 1 to 20 which is of omni-directional design and curved design and has cluster arrangements forming a circle or a cylinder envelope. 25. Flush-marker light as claimed in one of claims 1 to 24, whose semiconductor elements (1) are arranged in rows and columns. 26.Flush-marker light as claimed in one of claims 1 to 24, whose semiconductor elements (1) are arranged in circles or cylinders. 27. Flush-marker light as claimed in one of claims 1 to 26, whose semiconductor elements have an emitting section (2) in the shape of an aspherical lens. 28.Flush marker light as claimed in one of claims 1 to 27, wherein the semiconductor elements (1) are constructed from an inorganic or organic materials in particular from plastic. 28 29. Flush-marker light as claimed in one of claims 1 to 28, wherein the clusters (3) form a compact unit with a housing (15) of the flush-marker light. 30.Flush-marker light as claimed in one of claims 1 to 29, wherein there is arranged in front of the semiconductor elements (1) a cover plate by means of which the beams emitted by the semiconductor elements (1) can be influenced optically. 31.Flush-marker light as claimed in claim 30, wherein the beams can be focused and directed by means of the cover plate (7). 32.Flush-marker light as claimed in claim 29 or 30, wherein an optical device for beam diffraction and / or total reflection is assigned to the semiconductor elements (1). 33. Flush-marker light as claimed in one of claims 30 to 32, wherein the outside of the cover plate (7) can easily be cleaned and cured. 34.Flush-marker light as claimed in claim 33, wherein the outside of the cover plate(7) is coated. 35.Flush-marker light as claimed in one of claims 1 to 34, whose semiconductor elements (1) are arranged embedded in a filler body (8). 36.Flush-marker light as claimed in claim 35, wherein the filler body (8) of the semiconductor elements (1) has a cutout (9) at their active surface or light exit aperture (2). 29 37. Flush-marker light as claimed in claim 35 or 36, whose filler body (8) is constructed from a transparent material, for example a transparent resin, in particular epoxy resin, the refractive index of which corresponds approximately to that of the cover plate (7). 38. Flush-marker light as claimed in one of claims 1 to 37, wherein one or more clusters (3) of the flush marker light is/are designed as exchangeable sub unit, in particular as a cassette (20). 39. Flush-marker light as claimed in claim 38, wherein the cassette (20) is type coded. 40. Flush-marker light as claimed in claim 39, wherein there are constructed on the outside of the cassette (20) projections and depressions, respectively, which are assigned to depressions and projections, respectively, on the holder (21), accommodating the cassette (20), of the flush-marker light. 41.Flush-marker light as claimed in one of claims 38 to 40, wherein the basic body or the housing of the cassette (20) is filled entirely or partially with an electrically non conducting material, for example resin or plastic. 42. Flush-marker light as claimed in one of claims 38 to 41, wherein a non-conducting filler, for example glass, is added to the electrically non conducting material. 43.Flush-marker light as claimed in one of claims 38 to 42, wherein the walls, in particular a bottom wall of the basic body or the housing of the cassette (20) are or is constructed as thermal conductor, for example made from stainless steel or aluminium. 30 1 44.Flush-marker light as claimed in one of claims 38 to 43, wherein the outside of the cassette (20) is provided with a hardened portion, at least on the regions principally stressed. 45. Flush-marker light as claimed in one of claims 1 to 44, whose basic body or housing is constructed from a non-metallic and electrically non-conducting material. Dated this 7th day of July, 1997. Of L.S.DAVAR & CO. APPLICANTS' AGENT. This invention relates to a Lighting device for signaling, designating or marking, comprising plurality of different light sources designed as semiconductor elements (1), for example light-emitting diodes (LEDs) or light-emitting polymers, characterized in that the lighting device has a control means (22) by means of which the intensity of the light emission of the semiconductor elements (1) is variable in a controlled fashion.

Full Text

1A
The invention relates to a lighting device for signalling, designating or marking, having light sources which are designed as semiconductor elements, for example as light-emitting diodes (LEDs) or as light-emitting polymers.
It is possible by means of such semiconductor elements for light to be emitted from a lighting device outlined above in a prescribed colour, without there being a need for any sort of optical radiation filtering. Accordingly, such a semiconductor element scarcely generates radiation outside the visible region, in particular scarcely generates heat-generating infrared radiation or ultraviolet radiation. The outlay on power for operating such a semiconductor element or a lighting device having such semiconductor elements is thus low.
It is the object of the invention to make available, starting from the prior art outlined above, a lighting device whose light emission can be adapted in a simple way to different requirements and to different light conditions.
This object is achieved according to the invention owing to the fact that the lighting device has a control device by means of which the intensity of the light emission of the semiconductor elements is variable in a controlled fashion. As a result, the light emission of the lighting device can be adapted to the most different conditions by varying the intensity with which the semiconductor elements emit light. Since, even when their light emission is controlled with regard to intensity, such semiconductor elements emit light with a range of wavelengths which is very narrow and constant, the colour of the light emitted from the lighting device is the same for a different intensity of- the emitted light. -Adapting the light emission of the semiconductor elements to changes prescribed by the control device is performed in

- 2 -
microseconds, as a result of which the lighting device according to the invention can also satisfy strict requirements.
If the lighting device according to the invention has different semiconductor elements for emitting light in different colours, it being possible for the emitted light of different semiconductor elements to be mixed arbitrarily, the light emitted from the lighting device can be set arbitrarily with regard to colour and/or intensity. It is therefore possible to use one and the same lighting device to emit light of different col-our. The efficiency of such a lighting device can be increased by virtue of the fact that the semiconductor elements emit their light with a very narrow colour bandwidth and at a very high saturation. Since the colour of the emitted light does not change perceptibly with control of the intensity; the colour setting can be selected with respect to the efficiency. Using a lighting device according to the invention configured in such a way, light can be emitted virtually in the entire visible colour range, all colours which can be used sensibly in a technical way being possible.
This does not require any mechanical movement of lamps, filters or other parts to be moved physically; the corresponding properties of the lighting device according to the invention follow from static, controlled components. The addition of colours which are generated by individual semiconductor elements means that the light visible to the human eye can be of any colour, since it is no longer possible to resolve the light of different semiconductor elements after two arc minutes corresponding to a distance of 0.5 m from the lighting device.
The lighting device can expediently be dimmed and/or switched by means of the Control device) serving to control the power supply..
When this control device has an electronic light controller, the sensitivity of the semiconductor elements can be adapted to the customary sensitivity of incandescent lamps and tungsten-arc lamps, so that the light-

- 3 -
ing device according to the invention can be combined in the same system with conventional lighting devices having tungsten-arc lamps and incandescent lamps.
The control device can be connected for signalling purposes to a central unit by a power supply line and/or a separate electric or optical data line. The control device can serve to control the intensity of emission of the semiconductor elements. Moreover, it can be prescribed by means of the control device in which of several possible directions light is emitted, if the lighting device is designed as a bidirectional or omnidirectional lighting device.
By means of this control device the intensity of emission and the number of the semiconductor elements emitting light of different colour can be set so that the lighting device can be used to emit light of any desired colour at any desired intensity.
Moreover, the control device can set a specific succession of OFF and, if appropriate different, ON operating states.
Of course, it is possible in accordance with an advantageous embodiment of the lighting device according to the invention to use the control device to monitor the operating state and the operability of the semiconductor elements functioning as light source.
When the lighting device according to the invention has semiconductor elements which emit red, green or blue light and are arranged alternately, it is possible in particular for the variable white light which is particularly important in operating an airport to be emitted in any desired form. As a result, the lighting device can be adapted in an optimum way to different climatic conditions, it naturally being possible, in addition, to take account of different lighting conditions as well. Since red, blue and green are arranged at the outer corners of a colour triangle, and the lighting device can have a desired number of corresponding semiconductor elements, this lighting device can be used to generate all the colours. Moreover, the lighting device

- 4 -
according to the invention can be used immediately to fulfil the requirements with regard to light propagation.
If the aim is to use the lighting device according to the invention to emit only red, yellow, orange and green light, it is sufficient if it has semiconductor elements which emit red or green light and are arranged alternately. Semiconductor elements emitting blue light are not required in this case, since they are not important for the emission of light in the abovementioned colours. If light is to be generated only in the said four colours, specifically red, yellow, orange and green, the result of dispensing with semiconductor elements emitting blue light is that the lighting device according to the invention can be configured with smaller dimensions in conjunction with the same possible light intensity.
It is possible to arrange mutually juxtaposed rows of semiconductor elements of a cluster offset relative to one another, resulting in some circumstances in a denser population of a substrate with semiconductor elements.
If the control device of the lighting device according to the invention has a pulse-width modulation device by means of which the electrical power fed to the semiconductor elements can be controlled, the result is a high efficiency for operating the lighting device according to the invention, it being possible for the power rendered available to be adapted in an optimum way to the requirements of the lighting device or the requirements of the semiconductor elements by means of the pulse-width modulation device. There is, no need for a thyristor- controlled power supply which, in its turn, would typically cause harmonization and reactive losses in the main source. Moreover, the operation of the lighting device according to the invention produces no stroboscopic effect which could impair the correct perception of the lighting device.
It is possible for a plurality of semiconductor elements of the lighting device to form a cluster, it

- 5 -
being possible for 2 to 200, preferably 2 to 30, semiconductor elements to belong to a cluster. The failure of semiconductor elements can be compensated thereby, since a cluster having a plurality of semiconductor elements remains operable even when one or more semiconductor elements fail.
In an advantageous embodiment, the lighting device according to the invention can be designed as a cluster arrangement of a plurality of individual clusters, for example, of 1 to 30, preferably 1 to 16. The spatial light distribution of the lighting device can thereby be optimized in accordance with the prescribed requirements. The global photometric properties of the lighting device are determined by the cluster arrangement .
In an advantageous embodiment of the lighting device according to the invention, the semiconductor elements of a cluster, which are preferably designed without a mounting, are arranged on a common substrate.
When the substrate holding the semiconductor elements is provided on its side facing the semiconductor elements with a layer made from a reflecting material, it is ensured that the radiation components of the semiconductor elements which are not directed towards the radiation-emitting surface of the cluster or of the lighting device are deflected there as far as possible.
In accordance with one embodiment of the lighting device according to the invention, in which there is arranged on the output side of the semiconductor elements a mirror surface by means of which the direction of emission of the semiconductor elements is deflected, the direction of emission of the lighting device can be provided virtually as desired, depending on the positioning of the mirror surface.
When the dimensions of the radiation-emitting surface of the lighting device correspond approximately to the area of the substrate holding the semiconductor elements, the result is an emission of light from the lighting device which is uniform and thus perceived as

- 6 -
pleasant.
When the lighting device according to the invention can be assembled in a modular fashion from possibly different clusters and/or cluster arrangements, it is possible to fit such a lighting device together without great outlay for virtually any conceivable use and any conceivable requirements.
Thus, for example, a lighting device, which is of bidirectional design and has two cluster arrangements of which each emits in a direction opposite to that of the other, can be used at an airport to indicate the centre line of a straight taxiway, and also as a stop light; if the lighting device has two cluster arrangements which emit light in directions inclined to one another, they can be used on curved sections of taxiways to indicate the centre line thereof, or as a stop-light.
When the cluster arrangements of this lighting device have a plurality of, for example three or five, clusters arranged next to one another, mutually juxtaposed clusters respectively enclosing an angle of less than 180 degrees, it is possible to optimize the spatial distribution of the light emitted from the lighting device.
If the lighting device is intended to be of omnidirectional design, it is advantageous when its cluster arrangements are of curved design and form a circle or the lateral surface of a cylinder.
If the lighting device is to emit light in two directions, it is advantageous when the semiconductor elements are arranged in rows or in columns. If the lighting device is to emit light omnidirectionally, an arrangement of the semiconductor elements in circles or cylinders is advantageous. However, other arrangements of the semiconductor elements are also possible.
Owing to the reflecting configuration of the side of the substrate facing the semiconductor elements, it is possible to provide an elementary optical system in cooperation with the radiation-emitting sections of the semiconductor elements themselves, if the emitting

- 7 -
sections of the semiconductor elements have the form of an aspherical lens. The use and the distribution of the generated light can hereby be of optimum configuration.
The semiconductor elements of the lighting device according to the invention can be constructed from an inorganic or organic material, in particular from plastic. This yields substantial advantages with regard to weight and to the possibilities of production.
Moreover, the individual clusters can be cast or injected from a plastic, it being possible to use a recyclable plastic as plastic. It is possible to select a material which is a good conductor of heat for the individual clusters, it also being possible to use a pressure-resistant plastic.
If the clusters form a compact unit with a housing of the lighting device, this dispenses with any sort of hollow convection space.
When there is arranged in front of the semiconductor elements of the lighting device according to the invention a cover plate by means of which the beams emitted from the semiconductor elements can be influenced optically, it is possible to improve the emission of light from the lighting device, for example by focusing and aligning the beams.
The semiconductor elements can be assigned an optical device for beam refraction and/or total reflection, it being possible to provide a high-performance optical system by means of which the light emission can be optimally formed so that it satisfies in any case the requirements, already mentioned at the beginning, occurring in airport operation.
If the outside of the cover plate is easy to clean and is hardened, the outlay on maintenance for the lighting device can be reduced. The outside of the cover plate should expediently be of self-cleaning design, it being possible for the cover plate to be coated in a suitable way.
A compact configuration of the lighting device can be achieved when the semiconductor elements are

- 8 -
arranged embedded in a filler member.
If the filler member embedding the semiconductor elements has a cutout on the active surface or the light-emitting opening of the semiconductor elements, it is possible to maintain the use of the previously explained elementary optical system, to which the reflecting configuration of the side of the substrate facing the semiconductor elements and the aspherical lens on the emitting section of the semiconductor elements belong.
In accordance with an advantageous embodiment of the lighting device according to the invention, the filler member is constructed from a transparent material, for example a transparent resin, in particular epoxy resin, whose refractive index approximately corresponds to that of the cover plate. Optical losses on the transition surface between the filler body and the cover plate are hereby eliminated.
The individual semiconductor elements are expediently constructed such that they can be manipulated in a fully or partly automatic fashion.
The clusters of the lighting device according to the invention are expediently components of a redundantly operating system, with the result that it is possible in any case reliably to prevent a total failure of the lighting device according to the invention. Since, because of the redundant configuration of the system formed by the clusters, not every failure of an individual semiconductor element need necessarily lead to the exchange of a cluster, the outlay on maintaining the lighting device according to the invention can be further reduced.
In order further to simplify the assembly, the modification or the repair of the lighting device according to the invention, it is advantageous when one or more clusters of the lighting device is or are designed as an exchangeable subunit, in particular as a cassette. It is then possible for a cassette belonging to the lighting device to be exchanged in situ.
Such a cassette is advantageously type coded, so

- 9 -
that it can be installed in the lighting device exclusively in accordance with its arrangement prescribed in the lighting device; as a result, it is virtually impossible to make errors when replacing such cassettes in situ.
In an advantageous embodiment, it is possible for the purpose of realizing this type coding for there to be constructed on the outside of the cassette projections or depressions which are assigned to depressions or projections, respectively, on the holder of the lighting device which holds the cassette. In the case of the cassette and in the case of the holder on the side of the lighting device, such projections or depressions can contribute to their reinforcement and capacity to resist shear stresses. Loads and stresses introduced onto the cassette can be transferred by means of the holder onto the roadway, it being possible for these to be both mechanical, specifically static and dynamic loads, and thermal loads resulting from the requirement for thermal dissipation. For the purpose of connecting the cassette, a mounting for electrical contacts which is sealed off against the environment is provided on the holder; in order to connect the cassette in the desired way to a power supply, the holder can also have a part for power supply and control.
When the basic body or the housing of the cassette is filled entirely or partly with an electrically non-conducting material, for example resin or plastic,, electrical corrosion can be avoided.
If a non-conducting filler, for example glass, is added to the electrically non-conducting material, the thermal capacity for dissipation and load carrying of the cassette can be increased. The thermal resistance between the clusters present in the cassette is lowered, with the result that the transfer of heat between the clusters and the basic body or the housing of the cassette is based on thermal conduction instead of convection. Since there are no cavities inside the cassette, the cassette is inherently watertight and gastight.

- 10 -
If the walls, in particular a bottom wall of the basic body or of the housing of the cassette, are or is designed as thermal conductors, for example, made from stainless steel or aluminium, the temperature gradient inside the cassette can be reduced.
The outside of the cassette is advantageously provided with a hardening, at least on the main stress regions; as a result, damage owing to abrasion, scratches or point loads can be avoided to a very great extent. Moreover, such a reinforcement, in particular at the fastening points of the cassette, can have the effect that the load stresses and shear stresses can be better distributed on the holding part of the lighting device. Externally exposed surfaces of the cassette or of the entire lighting device can be hardened by means of sapphire or appropriate glass, so as to avoid a degradation of the efficiency of the lighting device owing to abrasion, or physical or chemical damage.
As already set forth above at the appropriate juncture, the lighting device according to the invention can be provided for signalling on as well as designating and marking traffic areas in airports, for example runways, taxiways and the like. It can be designed straight away in accordance with the standards valid in air traffic and for airports, for example ICAO, FAA, DOT, CIE, MIL-C-25050.
In one configuration of the lighting device as a flush-marker light, the absence of cavities ensures that, when driven over by a vehicle or an aircraft, the lighting device or the cassettes forming it are not exposed to bending stresses, but exclusively to compressive stresses. Since in the case of a lighting device configured in this way as a flush-marker light the rise in temperature owing to the operation of the light sources is less than 2 0% of the rise in temperature in the case of conventional lighting devices, the stresses from the aircraft tyres crossing the flush-marker light' can be substantially reduced. Moreover, the risk of burns can be substantially excluded for operating personnel.

-li-
It is also possible to configure the lighting device according to the invention such that it can be used to designate and mark traffic areas in road traffic, for example for roadway direction displays, roadway lane markings, speed restriction displays and the like.
Moreover, it is also possible to consider a configuration of the lighting device according to the invention for operating in navigation, for example for beacon lights, navigation channel displays, buoy markings and the like.
In accordance with an advantageous configuration of the invention, the basic body or the housing of the lighting device is constructed from a metallic and electrically non-conducting material. The use of such materials for lighting devices in airports has not so far been practicable, since the tungsten-arc lamps and incandescent lamps used as light sources have generated excessively high temperatures. Since the metallic and electrically non-conducting materials which can be used in the case of the invention are electrically isolating, no electrical corrosion occurs in the case of the light-ing device according to the invention. The material provided in the case of the lighting device according to the invention can be formed into virtually any shape with a low outlay. It can, moreover, serve as a thermal conductor, in order to dissipate the heat generated by the lighting device to the mounting part holding the lighting device, or to the roadway. Since the entire basic body or the entire housing of the lighting device according to the invention can be designed as an insulator by selecting the material which can now be used, no costly separate insulator is required. A recyclable plastic can be used for the basic body or the housing of the lighting device, the outcome being the ecological advantages resulting therefrom. Since the materials which can now be used to configure the lighting device according to the invention have a substantially longer lifetime by comparison with the prior art, the use cycles of the lighting device according to the invention are correspon-

- 12 -
dingly lengthened.
The semiconductor elements of the lighting device according to the invention can be controlled electrically between very low and very high potentials, the range of wavelengths of the emitted radiation being very narrow over the entire control range and entirely constant with regard to position and width, with the result that light of one and the same colour can be emitted over the entire control range.
The invention is explained in more detail below
with the aid of exemplary embodiments and with reference to the accompanying drawing, the application of the invention in the
field of airports, in particular, being described.
Figure 1 shows a representation of the principle of a semiconductor element designed as a light-emitting diode;
Figures 2 to 4 show, in front, side and top views, the principle of a first embodiment of a cluster of a lighting device according to the invention;
Figures 5 to 7 show, in front, side and top views, the principle of a second embodiment of a cluster of the lighting device according to the invention;
Figure 8 shows a top view of a first exemplary embodiment of the lighting device according to the invention;
Figure 9 shows a top view of a second exemplary embodiment of the lighting device according to the invention;
Figure 10 shows a top view of a third exemplary embodiment of the lighting device according to the invention;
Figure 11 shows a sectional representation of the exemplary embodiment, represented in Figure 8 for example, of the lighting device according to the invention;
Figure 12 shows a representation corresponding to Figure 11, the lighting device being constructed from clusters in accordance with Figures 5 to 7;
Figure 13 shows a further embodiment of the

- 13 -
lighting device according to the invention;
Figures 14 to 17 show representations of the principle of clusters having different semiconductor elements;
Figure 18 shows a representation of the fixed colours provided for airport lighting systems;
Figure 19 shows a representation of the principle of the control, regulation and monitoring of airport lighting systems;
Figure 20 shows a representation of the principle of the output side of a pulse-width modulation device of the lighting device according to the invention;
Figure 21 shows a control device of the lighting device according to the invention; and
Figure 22 shows a modified control device of the lighting device according to the invention.
A lighting device according to the invention has a multiplicity of semiconductor elements which are designed in the case of the embodiments described below as light-emitting diodes 1. The light-emitting diode 1 represented in principle in Figure 1 has, in that region in which the light generated emerges from the diode 1, a configuration as an aspherical lens 2, as is represented, in particular, in Figure 1.
Owing to the aspherical configuration of the light-refracting lens 2, the distribution of the light emitted by the diode 1 can be optimized.
The light-emitting diode 1 is, in particular, a bright or superbright LED.
The lighting device according to the invention is assembled from a multiplicity of previously described light-emitting diodes 1. A plurality of such light-emitting diodes 1 can be combined to form a cluster 3 represented in Figures 2 to 4. In the exemplary embodiment represented in Figures 2 to 4, the cluster 3 has ten light-emitting diodes 1, which are arranged in two rows, of five light-emitting diodes 1 each, arranged one above another.
It is possible for the centre lines of the diodes

- 14 -
1 of a row to be arranged inclined with respect to the centre lines of the diodes 1 of a neighbouring row.
All the light-emitting diodes 1 of this cluster 3 are arranged without a mounting on a substrate 4 which serves as a holder for the light-emitting diodes 1. The cluster 3 has an elementary optical system, to which there belongs a reflecting layer 5 which is applied to the side of the substrate 4 facing the light-emitting diodes 1. The aspherical lenses 2 of the light-emitting diodes 1, which optimize the use and distribution of the light generated by the light-emitting diodes 1, belong to this elementary optical system. The aspherical lens 2 respectively forms the actual active surface or the light-emitting opening of the light-emitting diodes 1.
The cluster 3 represented in Figures 2 to 4 is configured as a module part which can be assembled with other identical or similar clusters 3. On the light-emitting surface 6, the cluster 3 is closed by means of a cover plate 7 which, in the case of the cluster 3 represented in Figures 2 to 4, is arranged parallel to the substrate 4. With regard to its dimensions, the radiation-emitting surface 6 of the cluster 3 corresponds essentially to the surface of the substrate 4, which is virtually completely covered by the light-emitting diodes 1.
The light-emitting diodes 1 of the cluster 3 are surrounded by a filler member 8 which fills up the space between the substrate 4 and the cover plate 7 and is produced from a transparent material, for example from a resin. The filler member 8 has a cutout 9 which is assigned directly to the emitting section of the cluster 3 formed by the aspherical lenses 2 of the light-emitting diodes 1 of the cluster 3; the cutout 9 is constructed between the active surface of the light-emitting diodes 1 of the cluster 3 and the filler member 8, in order not to lose use of the elementary optical system formed by the reflecting layer 5 of the substrate 4 and the aspher-ical lenses 2 of the light-emitting diodes 1.
The refractive index of the material forming the

- 15 -
filler member 8 expediently corresponds to that of the material forming the cover plate 7. As a result, optical losses at the contact surface between the filler member 8 and the cover plate 7 can be prevented.
The outside of the cover plate 7 of the cluster 3 is of hardened and smooth configuration; it can, moreover, be self-cleaning.
In the embodiment of the cluster 3, as it is represented in Figures 2 to 4, the direction of emission, represented by the arrow in Figure 3, of the cluster 3 is arranged perpendicular to the plane of the substrate 4.
In the embodiment, represented by Figures 5 to 7, of the cluster 3, the direction of emission, represented by the arrow in Figure 6, of the cluster 3 is deflected by 90 degrees, for which purpose a mirror surface 10 is provided which is arranged between the light-emitting diodes 1 and the radiation-emitting surface 6 of the cluster 3. The mirror surface 10 resets the light beams by 90 degrees in the exemplary embodiment represented, with the result that they emerge parallel to the plane of the substrate 4 from the cluster 3 through the light-emitting surface 6 thereof or through the cover plate 7 thereof.
A taxiway centre and stop light for a straight section of a taxiway is represented in Figure 8. What is involved in this case is a so-called bidirectional lighting device, having a first cluster arrangement 11, which emits in the direction marked by the arrow 13, and a second cluster arrangement 12, which emits in the direction opposite to that of the cluster arrangement 11 and marked by the arrow 14.
The lighting device represented in Figure 8 is a compact device, the two cluster arrangements 11, 12 being arranged in a common housing 15. That region of the interior of the housing 15 which is arranged between the two cluster arrangements 11, 12 as well as, in Figure 8, to the side of the two cluster arrangements 11, 12 is filled with a suitable material. The housing 15 can be of metal construction.

- 16 -
Apart from the fact that they emit in different directions, the cluster arrangements 11, 12 correspond to one another, and so only the cluster arrangement 11 on the right in Figure 8 is described in detail below.
The cluster arrangement 11 has three clusters 3, which are arranged in a row next to one another, it being possible for each of these clusters 3 to have, for example, the embodiment represented by Figures 2 to 4. The middle cluster 3 is arranged at right angles to the centre line 16 of the taxiway, intersecting this centre line 16 in its middle region. The two outer clusters 3 respectively enclose with the middle cluster 3 an angle which is slightly less than 180 degrees. An efficient horizontal light distribution is achieved hereby. The cover of the lighting device represented in Figure 8 has a hardened, smooth outer surface which is thereby configured such that it can be cleaned in a simple way.
The lighting device represented in Figure 9 likewise serves for marking the centre line of a taxiway, but on a curved section thereof, and as a stop light which can be used there. It differs from the lighting device represented in Figure 8 by virtue of the fact that the directions of emission of the two cluster arrangements 11, 12 are inclined to one another, and that there are provided per cluster arrangement 11, 12 five indi -vidual clusters 3, which can likewise be such as the embodiments represented in Figures 2 to 4 . Since a curved section of the taxiway is involved, the middle cluster 3 of the two cluster arrangements 11, 12 is offset and inclined to the centre line CL of the lighting device. The clusters 3 of the two cluster arrangements 11, 12 likewise enclose with the respectively adjacent cluster 3 an angle alpha which is less than 180 degrees.
Figure 10 shows a lighting device which acts in all directions and can likewise be provided for marking a taxiway. Six curved clusters 17, which form a closed circle with one another and are separated from one another by structural ribs 18, are provided in the embodiment represented. Light can be emitted virtually in

- 17 -
all directions by means of the six curved clusters 17.
In the lighting devices described above with the aid of Figures 8 to 10, the outer optical surface can be of transparent and hard configuration, for example made from sapphire or glass with a hardened surface, so that a degradation of the efficiency of the lighting devices because of abrasion and physical or chemical damage is avoided. The outer optical surface can be hardened or coated in such a way that any possible Fresnel losses are reduced.
Represented in Figures 11 and 12 are cross-sections through lighting devices, which correspond, for example, to the lighting devices represented in Figures 8 to 10, and are designed as flush-marker lights. They differ from one another essentially in that, in Figure 11, the clusters 3 of the embodiment described with the aid of Figures 2 to 4 are used, whereas in the case of the flush-marker light in accordance with Figure 12 use is made of clusters of the embodiment explained with the aid of Figures 5 to 7.
The lighting device in accordance with Figures 11 and 12 is arranged with substantial parts below ground level 19. The arrows represented in Figures 11 and 12 mark the directions of emission of the flush-marker lights. As follows, in particular, from Figure 11, the part of the flush-marker light having the cluster or clusters 3 is configured in the form of a cassette 2 0 which, as such, forms a unit which can be exchanged without a high outlay. Such a flush-marker light can have one or more such cassettes 20. Depending on the configuration of the lighting device, a plurality of identical or, possibly, also different cassettes can be assembled to form the lighting device.
In an advantageous embodiment, such a cassette 2 0 is type coded, the type coding corresponding to its arrangement inside the lighting device. As a result of this, errors are rendered virtually impossible during an in situ replacement of the cassette 20. The type coding can be implemented by projections or cutouts on the

- 18 -
cassette side, corresponding cutouts or projections then being provided in a holding part 21 of the lighting device. Such relief-type configurations of the cassette 20 and of the holding part 21, or configurations provided with indentations can, moreover, contribute to the capacity to withstand shear stresses.
The basic body or the housing of the cassette 2 0 is filled entirely or partially with an electrically non-conducting material, for example a resin or plastic; electrical corrosion is avoided hereby. A thermally conducting material, for example glass, can be added to the non-conducting material, in order thus to increase the capacity of the cassette 20 for thermal dissipation and its capacity for accepting loads.
The thermal transmission between the clusters 3 and the basic body or the housing of the cassette 2 0 is then based on thermal conduction instead of air/gas convection, with the result that the thermal resistance of the cassette 2 0 is substantially reduced.
Since no convection gas is present, any possible aircraft or vehicle loads which act on the cassette 20 do not lead to bending stresses, but exclusively to compressive stresses, which can be absorbed or dissipated more easily.
The cassette 20 is inherently watertight and gastight, because there are no cavities, and thus no convection gas, inside the cassette 20.
The rise in temperature occurring in the cassette 20 is only less than 20% of the rise in temperature in the case of a lighting device with a conventional tungsten-arc light source, with the result that aircraft or vehicle tyres are by far less stressed, and burning of operating and maintenance staff can be excluded.
The bottom wall of the cassette 20 can be constructed by a thermal conductor, for example stainless steel or coated aluminium; the temperature gradient inside the cassette 20 is reduced hereby.
The outside of the cassette 20 can be constructed in a hardened fashion, for example from a stainless

- 19 -
steel, thus avoiding damage owing to abrasion, scratches or point loads.
Fastening points of the cassette 20 can be of reinforced design, so that load and shear stresses on the structure supporting the cassette 2 0 or on the holding part 20 can be distributed more effectively.
The introduction of power or the transmission of signals into the cassette 2 0 is accomplished by self -cleaning and self-sealing contacts. Watertight and vapourtight protection against the environment is provided.
Because of the design of the lighting device with light-emitting diodes 1, the transmission of electrical power between the cassette 2 0 and the remaining parts of the lighting device is performed at a very low voltage level, with the result that it is possible to carry out a "hot" cassette replacement without the danger of damaging the electrical contacts and without the risk of electric shock to the staff; in this case, the voltage level is below a peak voltage of approximately 25 V.
The cassette 20 is arranged above a power supply and control device 22 of the lighting device.
Since the cassette 20 is constructed as far as possible without cavities, it resists mechanical stresses of 100 G and vibrational stresses of up to 30 G, it being unimportant whether the lighting device is energized or not energized.
Loads and stresses introduced onto the cassette 20 are transferred onto the roadway by means of the holding part 21. These stresses are static and dynamic mechanical loads as well as thermal loads which arise from the need to dissipate the heat produced.
Figure 13 shows an embodiment of the lighting device which is arranged in a conventional way above a roadway. There, too, a cassette 20 configured to be capable of exchange in a modular fashion is arranged above a power supply and control device 22, the power supply and control device 22 being arranged above the ground level 19 with the aid of a detachable coupling 23.

- 20 -
Figure 14 shows a representation of the principle of a cluster 3 which is assembled from red, green and blue light-emitting diodes l. In a way still to be described, the intensity with which the light-emitting diodes 1 emit light of each colour can be controlled. Owing to the fact that the light-emitting diodes 1 of each of the three colours can emit light at the respectively desired intensity, light can be emitted virtually in all visible colours by means of the cluster 3 shown in Figure 14, it being possible, moreover, for this light to be emitted at different intensities. As follows, in par-ticular, in conjunction with Figure 18, the colours of red, green and blue provide the possibility of emitting light of any intensity and in any colour conceivable for possible signals.
Such a configuration of a cluster 3 can also be used to emit white light at different intensities, something which is difficult with conventional lighting devices. The reason for this is that red, green and blue are arranged in the colour spectrum approximately at the corners of a triangle which describes the visible colour range, as follows from Figure 18.
The light emerging from the cluster 3 can no longer be differentiated into individual light sources at a distance of two arc minutes corresponding to an observing distance of 10 m, with the result that light can be produced in the desired colour and intensity for all purposes. This also holds, in particular, for the standards ICAO, FAA, DOT, CIE, MIL-C-25050 valid in aviation.
A cluster 3 which, as already mentioned, contains light-emitting diodes 1 whose light is red, blue or green is best suited for generating variable white light. As already mentioned, these three colours are arranged at the outer corners of a triangle which is to be seen in Figure 18 and corresponds to the said standards.
Only four colours, specifically red (R), yellow (Y) , orange and green (G) are required to mark taxiway markings and route information. It is simpler and less expensive for such an application when a cluster 3

- 21 -
contains only two different types of light-emitting diodes 1, specifically ones which emit red light, and ones which emit green light. Such a cluster 3 is represented in principle in Figure 15. Diodes 1 emitting blue light can be dispensed with in this case.
The clusters 3 in accordance with Figure 16 and Figure 17 differ from the clusters 3 represented in Figure 14 and Figure 15 only by virtue of the fact that the individual light-emitting diodes 1 are not arranged in rows offset relative to one another; in the case of the clusters 3 in accordance with Figures 16 and 17, the light-emitting diodes 1 arranged below or above one another are not offset relative to one another.
Light-emitting diodes 1 are available on the market from different manufacturers and in different colours. Thus, for example, the Toshiba company manufactures LEDs for emitting light in red, orange and yellow colours; the Hewlett-Packard company manufactures diodes for emitting light in amber, orange, red-orange and red colours; the Ledtronics company manufactures diodes for emitting light in green, yellow, orange, red and blue colours.
The supply of power to the light-emitting diodes 1 is controlled with minimum losses by a pulse-width modulation device 24, the peak current being set in an initialization method by means of which the type of the light-emitting diode is identified in accordance with the result of a comparison of the voltage drop across a chain of light-emitting diodes with the voltage drop across a reference LED.
The control or inclusion and integration of the lighting devices according to the invention into a control system of an airport will now be explained with the aid of Figure 19.
An air traffic control centre 25, an emergency control centre 26 and a maintenance control centre 27 are connected in a suitable way to a controller 28 for routes and gates. This controller 28 is connected, in turn, to substations 29, 30, 31, of which only the substation 29

- 22 -
is represented in detail in Figure 19.
It may be pointed out that a star-shaped connec-tion between the controller 2 8 and the substations 29, 30, 31 is represented in Figure 19, but that it is also possible in principle to provide a loop connection or a bus connection.
The substation 29 has a subcontrol device 32 with a panel 33. Via a CCR 34 and a master circuit 35 in each case, the actual control devices 22 of the lighting devices according to the invention are connected to the subcontrol device 32.
The already mentioned pulse-width modulation device 24 belongs to the control device 22, which is represented in detail in Figures 21 and 22. The output power of the said pulse-width modulation device 24 can vary, as emerges from Figure 20, whose upper part represents an output power of the pulse-width modulation device 24 with a low intensity, and whose lower part represents an output power of the pulse-width modulation device 24 with a high intensity.
The control devices 22 represented in Figures 21 and 22 differ from one another only in that the control device 22 represented in Figure 21 has no separate data line 36, but has only a power supply line 37, which also serves the purpose of data transmission.
The control device 22 includes a power adapting and sensor unit 38 which is__connected to the pulse-width modulation device 24 and a controller 39.
The pulse-width modulation device 24 is likewise connected to the controller 3 9 and an outlet sensor 40, which is likewise connected to the controller 3 9 and via which the light-emitting diodes 1 of the lighting device are driven. The controller 39 is connected to the power supply line 37 or the data line 36 via a modem 41 and a connecting circuit 42.
A unit of the Intel 8051 type can be used as the controller 39. A PC can be used as the substation control device 32, a SICOMP-PC being a possibility.
The control of the lighting device includes the

- 23 -
regulation of the intensity of emission of the diodes 1,
the selection of that direction or those directions in
which light is to be emitted from the lighting device, the selection of the colour in which light is to be emitted, the light flash coding or the time sequence of light pulses, ON and/or OFF operation controlled as a function of time, monitoring of the diodes 1, and auto-matic "power on default start-up" selection and an automatic "fallback default" selection in the event of control failure. Further optional features are possible.
The input power incoming at the control device 22 is automatically detected and adapted to the requirements of the lighting device.
In the case of a standard constant-current series circuit input power, the output power of the pulse-width modulation device 24 is adapted such that the exponential response typical of tungsten-arc lamps or incandescent lamps is produced, with the result that the lighting device according to the invention can be combined with conventional lighting devices in one and the same circuit .
The modem 42 codes the modulated control signals from the power supply line 37 or the data line 36 and assigns the control signals. The modem 41 alternately modulates and codes monitoring signals which come from the Lighting device, in order to make these available to a central control and monitoring system. The modem 41 operates in two directions, in order to be able to transmit the control and monitoring signals in a suitable way.
A component of the control device 22 is a moni-toring part by means of which the lighting device is monitored for line interruption, earth fault, supply lead faults and the like.
The clusters 3 can, for example, also be moni-tored for operability by means of a selenium cell.

24
We Claim:
1. Flush-marker light for signaling on and identifying traffic areas, having light sources designed as semiconductor elements (1), for example as light-emitting diodes (LEDs) or as light-emitting polymers, different semiconductor elements (1) being provided in the form of clusters which in each case emit light of different colours, characterized in that the flush-marker light is suitably designed as an airport flush-marker light which can be rolled over by aircraft and is intended for lighting take-off runways, landing runways, taxiways and the like and has a control device (22) with a pulse-width-modulation device (24) by means of which the electrical energy fed to the semiconductor elements (1) can be regulated and the intensity of the light emission of the semiconductor elements (1) can thereby be varied in a controlled fashion.
2. Flush-marker light as claimed in claim 1, wherein the emitted light of different semiconductor elements (1) can be mixed at will by means of the control device (22).
3. Flush-marker light as claimed in claim 1 or 2, which can be switched by means of its control device (22) which serves the purpose of control and power supply.

4. Flush-marker light as claimed in one of claims 1 to 3, whose control device (22) has an electronic light regulator.
5. Flush-marker light as claimed in one of claims 1 to 4, whose control device (22) is connected for signaling purposes to a central unit by means of a power supply line (37) and /or a separate electric or optical data line (36).
5.
25
6. Flush-marker light as claimed in one of claims 1 to 5, by means of which the light can be emitted in a plurality of directions, and by means of whose control device (22) it is possible to select the direction of emission or the directions of emission.
7. Flush-marker light as claimed in one of claims 1 to 6, by means of whose control device (22) the intensity of emission and the number of the semiconductor elements (1) emitting light of different colour can be set such that light of arbitrary colour can be emitted with arbitrary intensity by means of the flush-marker light.
8. Flush-marker light as claimed in one of claims 1 to 7, by means of whose control device (22) it is possible to set a specific sequence of off and different on operating states.
9. Flush-marker light as claimed in one of claims 1 to 8, by means of whose control device (22) the operating state and the serviceability of the conductor elements (1) can be monitored.
l0. Flush-marker light as claimed in one of claims 1 to 9, which has semiconductor elements (1) which emit red, green and blue light and are arranged alternately.
11.Flush-marker light as claimed in one of claims 1 to 9, which has semiconductor elements (1) which emit red and green light and are arranged alternately.
12. Flush-marker light as claimed in one of claims 1 to 11, wherein mutually adjacent semiconductor element rows are arranged offset from one another.
13.Flush-marker light as claimed in one of claims 1 to 12, wherein 2 to 200, preferably 2 to 30, semiconductor elements (1) form a cluster (3).

26
14. Flush-marker light as claimed in one of claims 1 to 13 which is designed as a cluster arrangement made from a plurality of individual clusters (3).
15. Flush-marker light as claimed in claim 14, wherein l to 30, preferably 1 to 16, clusters (3) form a cluster arrangement ( 11, 12).
16. Flush-marker light as claimed in one of claims 1 to 15, wherein the semiconductor elements (1) of a cluster (3) are arranged on a common substrate (4).
17. Flush-marker light as claimed in one of claims 1 to 16, whose individual semiconductor elements (1) are designed without holders.
18.Flush-marker light as claimed in claim 16 or 17, wherein the substrate (4) holding the semiconductor elements (1) is provided on its side facing the semiconductor elements (1) with a layer (5) made from a reflecting material.
19. Flush-marker light as claimed in one of claims 1 to 18, wherein there is arranged on the output side of the semiconductor elements (1) a mirror surface (10) by means of which the direction of emission of the semiconductor elements (1) is deflected.
20. Flush-marker light as claimed in one of claims 16 to 19, the dimensions of whose radiation exit surface (6) correspond approximately to the area of the substrate(4) holding the semiconductor elements (1).
20.
27
21.Flush-marker light as claimed in one of claims 1 to 20, which is of bi-directional design and has two cluster arrangements (11, 12) of which each emits light in a direction opposite to that of the other.
22. Flush-marker light as claimed in one of claims 1 to 20, which is of bi-directional design and has two cluster arrangements( 11, 12) which emit light in mutually inclined directions.
23. Flush-marker light as claimed in claim 21 or 22, wherein each cluster arrangement (11, 12) has a plurality of , for example three or five, clusters (3) arranged next to one another, mutually adjacent clusters (3) enclosing an angle of less than 180degrees in each case.
24. Flush-marker light as claimed in one of claims 1 to 20 which is of omni-directional design and curved design and has cluster arrangements forming a circle or a cylinder envelope.
25. Flush-marker light as claimed in one of claims 1 to 24, whose semiconductor elements (1) are arranged in rows and columns.
26.Flush-marker light as claimed in one of claims 1 to 24, whose semiconductor elements (1) are arranged in circles or cylinders.
27. Flush-marker light as claimed in one of claims 1 to 26, whose semiconductor elements have an emitting section (2) in the shape of an aspherical lens.
28.Flush marker light as claimed in one of claims 1 to 27, wherein the semiconductor elements (1) are constructed from an inorganic or organic materials in particular from plastic.

28
29. Flush-marker light as claimed in one of claims 1 to 28, wherein the clusters (3) form a compact unit with a housing (15) of the flush-marker light.
30.Flush-marker light as claimed in one of claims 1 to 29, wherein there is arranged in front of the semiconductor elements (1) a cover plate by means of which the beams emitted by the semiconductor elements (1) can be influenced optically.
31.Flush-marker light as claimed in claim 30, wherein the beams can be focused and directed by means of the cover plate (7).
32.Flush-marker light as claimed in claim 29 or 30, wherein an optical device for beam diffraction and / or total reflection is assigned to the semiconductor elements (1).
33. Flush-marker light as claimed in one of claims 30 to 32, wherein the outside of the cover plate (7) can easily be cleaned and cured.
34.Flush-marker light as claimed in claim 33, wherein the outside of the cover plate(7) is coated.
35.Flush-marker light as claimed in one of claims 1 to 34, whose semiconductor elements (1) are arranged embedded in a filler body (8).
36.Flush-marker light as claimed in claim 35, wherein the filler body (8) of the semiconductor elements (1) has a cutout (9) at their active surface or light exit aperture (2).

29
37. Flush-marker light as claimed in claim 35 or 36, whose filler body (8) is constructed from a transparent material, for example a transparent resin, in particular epoxy resin, the refractive index of which corresponds approximately to that of the cover plate (7).
38. Flush-marker light as claimed in one of claims 1 to 37, wherein one or more clusters (3) of the flush marker light is/are designed as exchangeable sub unit, in particular as a cassette (20).
39. Flush-marker light as claimed in claim 38, wherein the cassette (20) is type coded.
40. Flush-marker light as claimed in claim 39, wherein there are
constructed on the outside of the cassette (20) projections and
depressions, respectively, which are assigned to depressions and
projections, respectively, on the holder (21), accommodating the
cassette (20), of the flush-marker light.
41.Flush-marker light as claimed in one of claims 38 to 40, wherein the basic body or the housing of the cassette (20) is filled entirely or partially with an electrically non conducting material, for example resin or plastic.
42. Flush-marker light as claimed in one of claims 38 to 41, wherein a non-conducting filler, for example glass, is added to the electrically non conducting material.
43.Flush-marker light as claimed in one of claims 38 to 42, wherein the walls, in particular a bottom wall of the basic body or the housing of the cassette (20) are or is constructed as thermal conductor, for example made from stainless steel or aluminium.

30
1
44.Flush-marker light as claimed in one of claims 38 to 43, wherein the outside of the cassette (20) is provided with a hardened portion, at least on the regions principally stressed.
45. Flush-marker light as claimed in one of claims 1 to 44, whose basic body or housing is constructed from a non-metallic and electrically non-conducting material.
Dated this 7th day of July, 1997.

Of L.S.DAVAR & CO. APPLICANTS' AGENT.
This invention relates to a Lighting device for signaling, designating or marking, comprising plurality of different light sources designed as semiconductor elements (1), for example light-emitting diodes (LEDs) or light-emitting polymers, characterized in that the lighting device has a control means (22) by means of which the intensity of the light emission of the semiconductor elements (1) is variable in a controlled fashion.

Documents:

01276-cal-1997 abstract.pdf

01276-cal-1997 claims.pdf

01276-cal-1997 correspondence.pdf

01276-cal-1997 description(complete).pdf

01276-cal-1997 drawings.pdf

01276-cal-1997 form-1.pdf

01276-cal-1997 form-2.pdf

01276-cal-1997 form-3.pdf

01276-cal-1997 gpa.pdf

1276-CAL-1997-(02-04-2012)-CORRESPONDENCE.pdf

1276-CAL-1997-(02-04-2012)-FORM 27.pdf

1276-CAL-1997-(02-04-2012)-PA.pdf

1276-CAL-1997-(25-07-2012)-CORRESPONDENCE.pdf

1276-CAL-1997-(25-07-2012)-PA.pdf

1276-CAL-1997-(25-07-2012)-PETITION UNDER RULE 137.pdf

1276-CAL-1997-ASSIGNMENT.pdf

1276-CAL-1997-CORRESPONDENCE 1.1.pdf

1276-CAL-1997-FORM 16.pdf

1276-cal-1997-granted-abstract_.pdf

1276-cal-1997-granted-claims_.pdf

1276-cal-1997-granted-correspondence_.pdf

1276-cal-1997-granted-description (complete)_.pdf

1276-cal-1997-granted-drawings_.pdf

1276-cal-1997-granted-form 1_.pdf

1276-cal-1997-granted-form 2_.pdf

1276-cal-1997-granted-form 3_.pdf

1276-cal-1997-granted-gpa_.pdf

1276-cal-1997-granted-letter patent_.pdf

1276-cal-1997-granted-reply to examination report_.pdf

1276-cal-1997-granted-specification_.pdf

1276-CAL-1997-PA.pdf

1276-CAL-1997-PETITION UNDER RULR 138.pdf

« Previous Patent

Next Patent »

Patent Number

194180

Indian Patent Application Number

1276/CAL/1997

PG Journal Number

30/2009

Publication Date

24-Jul-2009

Grant Date

12-Aug-2005

Date of Filing

07-Jul-1997

Name of Patentee

SIEMENS AKTIENGESELLSCHAFT

Applicant Address

WITTELSBACHERPLATZ 2, 80333 MUENCHEN

Inventors:

#	Inventor's Name	Inventor's Address
1	JEAN -CLAUDE VANDEVOORDE	DIJKSTR.9, B-1820 STEENKOKKERZEEL

PCT International Classification Number

B64F 1/18

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA