DE102015114275A1 - Lighting device, method for operating a lighting device and system for lighting a vehicle - Google Patents

Abstract

An illumination device for a vehicle is specified. The illumination device comprises an organic light-emitting component (3), which is formed mechanically flexible deformable. In a first deformation state of the organic light-emitting component (3), the illumination device (1) has a first appearance, which differs from at least one further appearance in a respective further deformation state of the organic light-emitting component (3). The illumination device further comprises a deformation unit (7), which is designed to mechanically deform the organic light-emitting component (3). A method for operating a lighting device for a vehicle as well as a system for lighting a vehicle are also specified.

Description

A lighting device for a vehicle, a method for operating a lighting device for a vehicle and a system for lighting a vehicle are specified.

Organic light-emitting devices, in particular organic light-emitting diodes (OLEDs) could be used in the automotive sector. Exemplary segmented OLEDs could be used in lighting devices such as taillights of a vehicle, the segments of which are switched on or off separately depending on the situation. For example, by switching off individual segments depending on a driving mode, a luminous area of the lighting devices could become narrower or longer. However, such a procedure would require a corresponding segmentation of the OLED or additional OLEDs for areas of the illumination devices which can be switched on or off as well as separate control signals for the individual segments or OLEDs. In this case, the regions which can be switched on or off would determine a discrete gradation in the case of a change in a luminous area size of the illumination devices. In particular, a large number of separately controllable segments or OLEDs would be required for a fine gradation in the change of the luminous area size, which would in turn require a comparatively high associated effort for the control.

It is an object to provide a lighting device for a vehicle, a method for operating a lighting device for a vehicle and a system for lighting a vehicle, which contributes to a flexible and efficient operation of the lighting device.

According to a first aspect, a lighting device for a vehicle is specified. The lighting device is in particular a device for vehicle exterior lighting such as a headlight, a tail light or a direction indicator.

In at least one embodiment according to the first aspect, the illumination device comprises an organic light-emitting component, which is formed mechanically flexible deformable. The organic light-emitting component is, in particular, an organic light-emitting diode (OLED). The organic light-emitting component has a radiation characteristic that can be changed, for example, by its mechanical deformation.

The mechanical deformation of the organic light-emitting component designates a bending and / or buckling of the organic light-emitting component. For example, an undeformed organic light-emitting component has a substantially planar luminous surface, which can also be referred to as a lateral extent of the organic light-emitting component. The mechanical deformation can then result, by way of example, in that the organic light-emitting component has a curvature whose vertex is perpendicular to the original lateral extent. An externally perceptible luminous surface of the mechanically deformed organic light-emitting component can then, for example, have a reduced effect with respect to the planar luminous surface and / or have a perceptible depth. In particular, the emission characteristic of the organic light-emitting component can be changed by the mechanical deformation.

A mechanically flexible and / or reversible deformation in this context refers to a reproducible deformation, that is to say that the organic light-emitting component is designed to withstand a predetermined bending stress for a plurality of repetitions substantially without any damage.

In at least one embodiment according to the first aspect, a thickness of the organic light-emitting device is less than 400 μm. The thickness denotes an extent of the undeformed organic light-emitting component perpendicular to the lateral extent and may be less than 100 μm, in particular less than 50 μm, for example less than 30 μm. Advantageously, this contributes to a simple mechanical deformability of the organic light-emitting component.

In at least one embodiment according to the first aspect, the illumination device has a first appearance in a first deformation state of the organic light-emitting component. The first appearance of the illumination device differs from at least one further appearance of the illumination device, which has the illumination device in a respective further deformation state of the organic light-emitting component. In particular, the organic light-emitting component can have different emission characteristics in the first or respectively further deformation state.

The first or respective further deformation state of the organic light-emitting component can be a predetermined shape and / or comprise a predetermined size of the lateral extent of the light emitting device. Alternatively or additionally, the first or respective further deformation state comprises, for example, a predetermined angle, which includes a surface normal of the curved light-emitting component, for example at most with a main radiation direction of the illumination device and / or a predetermined distance, which has the apex perpendicular to the planar luminous surface. For example, the first or respective further deformation state may designate a predetermined deformation state such as a minimum or initial, a maximum or final deformation, or a predetermined intermediate step of the deformation of the organic light-emitting component. Independently of this, the mechanical deformation of the organic light-emitting component may be a continuous deformation, which is in particular not limited to predetermined deformation states of the organic light-emitting component.

The first or respectively further deformation state of the organic light-emitting component may alternatively or additionally comprise a maximum curvature, which is described by the curvature of the organic light-emitting component. The maximum curvature can be approximated by the curvature of a circle, for example at the vertex of the curvature. A radius of this circle may also be referred to as a bending radius that is representative of the maximum curvature of the organic light emitting device. The bending radius is, for example, less than 100 mm, depending on the respective deformation state. The bending radius may also be less than 50 mm, in particular less than 10 mm, for example less than 5 mm, depending on the respective deformation state.

The first or respectively further appearance of the illumination device is a luminous surface of the illumination device that can be recognized from the outside. Depending on a distance when viewing the illumination device, a change in the appearance may be limited to a variable lateral extent of the perceived luminous area. In addition, depending on the state of deformation, the organic light emitting device may be three-dimensionally perceptible, that is, the appearance has a three-dimensional depth by way of example.

In at least one embodiment according to the first aspect, the illumination device comprises a deformation unit which is designed to mechanically deform the organic light-emitting component.

For example, the organic light-emitting component has an initial shape, which forms the first deformation state. The deformation unit is then configured by way of example to deform the organic light-emitting component from the first deformation state into the respective further deformation state. By way of example, the organic light-emitting component can have an elasticity, so that its initial shape can be recovered without the action of the deformation unit. Alternatively or additionally, the deformation unit is designed to deform the organic light-emitting component from the respective further deformation state into the first deformation state. In particular, the deformation unit can be designed to deform the organic light-emitting component into at least two different states of deformation. In this context, it is conceivable that the deformation unit comprises one or more actuators. In particular, the respective deformation state can also be an undeformed state of the organic light-emitting component.

In at least one embodiment according to the first aspect, the illumination device comprises an organic light-emitting component, which is formed mechanically flexible deformable. In a first deformation state of the organic light-emitting component, the illumination device has a first appearance, which differs from at least one further appearance in a respective further deformation state of the organic light-emitting component. The illumination device further comprises a deformation unit which is designed to mechanically deform the organic light-emitting component.

Advantageously, the mechanical deformation of the organic light emitting device can be situation-dependent. In this case, the deformation and thus a transition between the respective appearances in contrast to a digital switching on or off laterally extended segments of the organic light-emitting components continuously, analogously. In addition, a perceptible three-dimensionality of the organic light emitting device may serve as additional information coding. By way of example, a perceivable three-dimensional depth of the camber may be representative of an intensity of an acceleration, such as a braking force applied in a current braking maneuver. This has the advantage that it can contribute to a flexible operation of the lighting device and safe operation of the vehicle. A drive for deformation of the organic light-emitting component can thereby Compared to segmented organic light-emitting components be particularly simple, so that further an efficient operation of the lighting device is made possible.

In at least one embodiment according to the first aspect, the illumination device comprises at least one further organic light-emitting component, which is flexibly designed to be mechanically deformable. The illumination device further comprises at least one further deformation unit, wherein the organic light-emitting components are each assigned a deformation unit for their mechanical deformation.

Advantageously, such an individual deformation of the individual organic light-emitting components can be made.

In at least one embodiment according to the first aspect, the illumination device comprises at least one further organic light-emitting component, which is formed mechanically deformable. The deformation unit is assigned to a plurality of organic light-emitting components for their mechanical deformation.

In an advantageous manner, a particularly efficient deformation of the individual organic light-emitting components can be carried out.

In at least one embodiment according to the first aspect, the illumination device comprises an organic light-emitting component, which is mechanically flexibly deformable, and at least two deformation units, which are assigned to the organic light-emitting component and designed to mechanically deform it.

In at least one embodiment according to the first aspect, the organic light-emitting component has a plurality of separately operable light-emitting segments.

This advantageously makes it possible to realize additional gradations and / or shapes of the respective appearances. In particular, the segments can be dimmable in their brightness.

In at least one embodiment according to the first aspect, the organic light-emitting component is mechanically fixed at least in places on at least one holder element. The deformation unit is designed for a displacement and / or deformation of the at least one holder element, such that the organic light-emitting component is mechanically deformed during the displacement and / or deformation of the at least one holder element.

In an advantageous manner, the mechanical deformation of the organic light-emitting component can be carried out in a particularly simple manner. In particular, this contributes to a wide variety of organic light-emitting devices that can be used in the lighting device.

In this context, the organic light-emitting component may be adhesively bonded to the holder element, for example only at its lateral end regions, so that a simple bending of the organic light-emitting component is made possible.

In at least one embodiment according to the first aspect, the illumination device comprises a housing. In the housing, the organic light emitting device and the deformation unit are arranged. The organic light-emitting component is at least locally fixed relative to the housing. The housing may in particular also be the housing of a vehicle headlight, a tail light or a direction indicator.

The deformation unit is designed to displace and / or deform at least a partial region of the organic light-emitting component relative to the housing, such that the organic light-emitting component is mechanically deformed during the displacement and / or deformation of the partial region.

In an advantageous manner, a particularly simple mechanical deformation of the organic light-emitting component can take place. In particular, this contributes to a wide variety of organic light-emitting devices that can be used in the lighting device.

In at least one embodiment according to the first aspect, the organic light-emitting component comprises a carrier which is at least locally magnetically formed. The deformation unit is designed for a displacement and / or deformation of the carrier, such that the organic light-emitting component is mechanically deformed during the displacement and / or deformation of the carrier. For example, the support is a substrate such as a steel or metal foil or a plastic film that includes at least a portion in which a magnetic material is mounted in or on the foil.

Advantageously, a particularly efficient mechanical deformation of one or more organic light-emitting components can thus take place. In an advantageous manner, a displaceable and / or deformable holder element can be dispensed with in this context.

In at least one embodiment according to the first aspect, the deformation unit as a displacing and / or deforming actuator comprises at least one of: electric motor, electromagnet, hydraulically operated actuator, pneumatically operated actuator, piezoelectrically operated actuator.

According to a second aspect, a method for operating a lighting device for a vehicle is specified. The illumination device is in particular the illumination device according to the first aspect. That is, all the features and feature combinations disclosed for the lighting device are also disclosed for the method of operating a lighting device, and vice versa.

The method provides an input signal that is representative of an operating mode of the vehicle. Depending on the input signal, an actuating signal is determined and provided to a deformation unit of the illumination device. Depending on the actuating signal, an organic light-emitting component of the illumination device is mechanically deformed by the deformation unit.

The mode of operation of the vehicle can include both a set driving mode such as "sporty" or "comfortable", as well as a detectable for example by vehicle sensors driving style, which is closed as an example of a comparatively rapid change of location of the vehicle on an agile driving style. Additionally or alternatively, the operating mode of the vehicle may further include a speed and / or an acceleration of the vehicle, as a function of which the mechanical deformation of the organic light-emitting component is controlled.

In at least one embodiment according to the second aspect, the organic light-emitting component is mechanically deformed such that a lateral extent of an appearance of the illumination device is changed.

Advantageously, the mode of operation of the vehicle can thus be signaled to other road users in a particularly intuitive manner. For example, a driver driving ahead can refrain from a lane change as early as when the vehicle is detected in the desired lane in an operating mode that signals a high speed.

In at least one embodiment according to the second aspect, the organic light-emitting component has a plurality of separately operable light-emitting segments. In the method, a further actuating signal is determined as a function of the input signal and provided to the organic light-emitting component. A respective light-emitting operation of the light-emitting segments is controlled as a function of the further actuating signal.

Advantageously, thus further gradations and shapes of the respective appearances of the illumination device can be generated.

In at least one embodiment according to the second aspect, a mechanical deformation of the organic light-emitting component is performed continuously.

According to a third aspect, a system for illuminating a vehicle is specified. The system comprises a lighting device with an organic light-emitting component and a preforming unit. In particular, it is a lighting device according to the first aspect. The system further includes a control unit configured to perform a method according to the second aspect. That is, all the features and feature combinations disclosed for the lighting device and the method for operating a lighting device are also disclosed for the system for lighting a vehicle, and vice versa.

Further features, embodiments and expediencies will become apparent from the following description of the embodiments in conjunction with the figures.

Show it:

1 A first embodiment of a lighting device for a vehicle in perspective view and in plan view,

2 A second embodiment of a lighting device for a vehicle in perspective view and in side view,

3 A third embodiment of a lighting device for a vehicle in a perspective view and in side view,

4 A fourth embodiment of a lighting device for a vehicle in perspective view and in plan view,

5 an embodiment of a system for lighting a vehicle, and

6 an exemplary flowchart for operating a lighting device according to the previous embodiments.

The same, similar or equivalent elements are provided in the figures with the same reference numerals. The figures and the proportions of the elements shown in the figures with each other are not to be considered to scale. Rather, individual elements may be exaggerated in size for better representability and / or better understanding.

A first embodiment of a lighting device 1 for a vehicle is based on the 1a - 1c schematically shown in both perspective view and in plan view. In the 1a shown section line AA 'is intended to illustrate the perspective relationship between the views.

At the lighting device 1 it is a motor vehicle exterior lighting, in particular a tail lamp of a vehicle. The lighting device 1 comprises several organic light-emitting components 3 . 5 , which can be controlled separately, for example, or together. In this embodiment, only two such organic light emitting devices 3 . 5 the lighting device 1 shown. Generally, a number of the lighting device 1 associated organic light emitting devices 3 . 5 deviate from two and in particular exceed. For example, the illumination device comprises 1 between 1 and 100 organic light emitting devices 3 . 5 ,

In the organic light emitting devices 3 . 5 these are in particular OLEDs. The organic light-emitting components 3 . 5 have a lateral extent, which is for a viewer of the lighting device 1 is perceived as a luminous surface. The organic light-emitting components 3 . 5 In this case, for example, they can be offset relative to one another in the vertical direction, that is to say essentially perpendicular to the lateral extent.

In particular, the organic light-emitting components 3 . 5 formed mechanically flexible deformable. In this context, the organic light-emitting components 3 . 5 exemplarily comparatively thin layers. As a substrate of the organic light-emitting components 3 . 5 In particular, plastic or metal foils can be used.

As in 1a represented form the organic light-emitting components 3 . 5 in a first deformation state, for example, in each case a planar surface in which a lateral extension of the perceptible luminous area is maximum. In this context, the organic light-emitting components 3 . 5 For example, overlap in the lateral direction. The perceptible luminous area of the light-emitting components 3 . 5 may also be the appearance of the lighting device 1 be designated.

1b and 1c each show a further deformation state of the organic light-emitting components 3 . 5 , In this case, the organic light-emitting components 3 . 5 in plan view in each case one with respect to a main radiation direction of the illumination device 1 convex curvature, wherein an axis of curvature parallel to a vertical axis of the illumination device 1 or the image plane is. The curvature leads to a reduction of the perceptible luminous area of the illumination device 1 , in particular the lateral extent parallel to a transverse axis of the illumination device 1 , In other words, depending on a respective deformation state, a size of a projection of the luminous area of the organic light-emitting devices changes 3 . 5 on a two-dimensional plane whose normal vector is parallel to the main radiation direction of the illumination device 1 is. Alternatively, but in particular in addition, the curvature can be perceived as a three-dimensional deformation. For example, the luminous area of the organic light-emitting components 3 . 5 then a perceptible spatial depth.

A second embodiment of the illumination device 1 is based on the 2a - 2c schematically shown in both perspective view and in side view. In the 2a shown section line BB 'is intended to illustrate the perspective relationship between the views.

The lighting device 1 In the second exemplary embodiment, by way of example only an elongate organic light-emitting component is provided 3 on. As in the 2a - 2c to see differing the respective deformation states of the organic light-emitting device 3 of the first embodiment by an alignment of the curvature. This is in the second embodiment with respect to the main radiation direction of the illumination device 1 concave formed, wherein an axis of the curvature parallel to the transverse axis of the illumination device 1 or the image plane is aligned. The curvature has the consequence, in particular, that the luminous area which can be perceived in the lateral direction, in particular the lateral extent, runs parallel to the vertical axis of the illuminating device 1 is reduced.

A third embodiment of the illumination device 1 is based on the 3a - 3c schematically shown in both perspective view and in side view. As in 2a serves the in 3a shown section line BB 'merely a clarification of the perspective relationship between the views.

The lighting device 1 In the third exemplary embodiment, by way of example only one organic light-emitting component is provided 3 on, which has a predetermined first shape as that of an arrow or the letter, V '. As in the 3a - 3c to see differing the respective deformation states of the organic light-emitting device 3 from the previous embodiments in that the organic light-emitting component 3 bent several times and / or as shown here kinked. For example, in this context, a parallel to the vertical axis of the illumination device 1 aligned end portion of the organic light-emitting device 3 fixed, for example on a housing of the lighting device 1 while an opposite, parallel to the vertical axis of the lighting device 1 aligned end portion along the transverse and / or vertical axis of the illumination device 1 is moved. This has in particular the consequence that the luminous area perceptible in the lateral direction, in particular the lateral extent, runs parallel to the vertical axis of the illuminating device 1 is reduced. Furthermore, in this case a perceptible, spatial overlap of the two end sections perpendicular to the main radiation direction of the illumination device 1 respectively. Furthermore, it is conceivable that in one of the further deformation states, the organic light-emitting component 3 takes another predetermined form, which differs from the predetermined first form and contains, for example, a different coded information, for example, an oppositely oriented arrow in comparison to the predetermined first shape.

A fourth embodiment of the illumination device 1 is based on the 3a - 3c schematically shown in both perspective view and in plan view. As in 1a serves the in 4a shown section line AA 'only one clarification of the perspective relationship between the views.

The lighting device 1 In the fourth exemplary embodiment, by way of example only an organic light-emitting component is provided 3 on, which in contrast to the previous embodiments, several separately operable

segments 3a . 3b . 3c . 3d . 3e . 3f includes. The hatched segments 3a ... 3f illustrate a light-emitting operation of the segments 3a ... 3f , As in the 4a - 4c to see an appearance of the lighting device 1 both by deformation of the organic light emitting device 3 , as well as by switching on or off of the individual segments 3a ... 3f to be influenced. Deviating from the representation in the 4a - 4c may alternatively or additionally a separate dimming of the brightness of the light-emitting segments 3a ... 3f done so that further gradations of the appearance of the lighting device 1 can be created. By curvature of the organic light emitting device 1 becomes analogous to 1 the perceptible luminous area of the illumination device 1 , In particular their lateral extent parallel to the transverse axis of the illumination device 1 reduced.

5 shows an embodiment of a system 11 for lighting a vehicle. The lighting device 1 with the organic light emitting device 3 is a deformation unit 7 associated with a mechanical deformation of the organic light emitting device 3 serves. By way of example, each organic light-emitting component is exemplary 3 such a deformation unit 7 assigned. Alternatively, by the deformation unit 7 several organic light-emitting components 3 be deformed.

The deformation unit 7 Here is only schematically outside the lighting device 1 arranged shown. Deviating from this is an arrangement of the deformation unit 7 Of course, also within the lighting device 1 conceivable, particularly preferably in spatial proximity to the respective light-emitting component 3 ,

The deformation unit 7 comprises as a deforming actuator, for example, an electric motor, which as indicated in the third embodiment, a portion or end portion of the organic light-emitting device 3 shifts so that it is mechanically deformed.

Alternatively or additionally, the deformation unit comprises 7 For example, a hydraulically, piezoelectrically or pneumatically operated, deforming actuator. By way of example, the organic light-emitting component 3 coupled to a surface of a balloon associated with the actuator, wherein a volume change of the balloon to a deformation of the organic light-emitting device 3 can be used.

Alternatively or additionally, the deformation unit comprises 7 as a deforming actuator, for example, an electromagnet. The organic light emitting device 3 For example, it is coupled to a holder member, such as a membrane. Furthermore, it is conceivable that a substrate of the organic light-emitting component 3 comprises or consists of a magnetic material, such as a ferromagnetic metal foil. The deformation of the membrane or of the organic light-emitting component 3 can then be controlled by generating a magnetic field.

The system 11 in this context continues to have a control unit 9 which leads to a control of the deformation unit 7 is trained. For example, the control unit 9 a structural unit with the lighting device 1 form, or be arranged separately to this, for example, to control a plurality of deformation units 7 various lighting devices 1 , In particular, the control unit comprises 9 a data and program memory in which a program for operating the lighting device 1 is stored as in the following with reference to the flowchart in 6 explained. The program is started in a step S1. For example, variables are initialized in this step. In particular, the control unit 9 provides an input signal representative of an operating mode of the vehicle. The operating mode of the vehicle may be, inter alia, a predetermined driving mode set by a vehicle occupant of the vehicle, such as "sporty" or "comfortable". Alternatively or additionally, the input signal includes, for example, data relating to a current position, a current speed, and / or further data that are representative of a driving style of the vehicle occupant. Optionally, a predetermined operating mode of the vehicle is determined in step S1 depending on these data. The program is then continued in step S3.

In step S3, an actuating signal is determined as a function of the input signal and the deformation unit 7 provided. The program is then continued in a step S5.

In step S5, the organic light emitting device becomes 3 depending on the actuating signal by the deformation unit 7 mechanically deformed. In the event that it is a "sporty" mode of the vehicle, which is characterized for example by comparatively strong acceleration phases and / or a high maximum speed, other road users by appropriate deformation of the organic light-emitting components 3 by way of example by narrowing the perceptible light surface and / or deforming the organic light-emitting components 3 to arrows or other forms containing information, this fact should be pointed out. Advantageously, this contributes to a high level of road safety.

By way of example, a narrowing of the perceptible light surface can be effected in proportion to the current speed and / or acceleration of the vehicle. Alternatively, a distinction is made between two or more stages of the operating mode of the vehicle, which in each case predetermined forms of the organic light-emitting components 3 be assigned. By way of example, in the case of inner-city operation of the vehicle, a perceptible three-dimensional appearance of the illumination device is achieved 1 used.

For example, in this context, a brightness of a light-emitting operation of the segments 3a ... 3f of the organic light emitting device 3 through the control unit 9 to be controlled.

The invention is not limited by the description with reference to the embodiments. Rather, the invention encompasses any novel feature as well as any combination of features, including in particular any combination of features in the claims, even if this feature or combination itself is not explicitly stated in the patent claims or exemplary embodiments.

Claims (14)

Lighting device ( 1 ) for a vehicle, comprising - an organic light emitting device ( 3 ), which is formed mechanically flexible deformable, wherein the illumination device ( 1 ) in a first deformation state of the organic light-emitting device ( 3 ) has a first appearance which differs from at least one further appearance in a respective further deformation state of the organic light-emitting component ( 3 ), and - a deformation unit ( 7 ), which is formed, the organic light-emitting component ( 3 ) mechanically deform. Lighting device ( 1 ) according to claim 1, comprising At least one further organic light-emitting component ( 5 ), which is formed mechanically flexible deformable, and - at least one further deformation unit ( 7 ), wherein the organic light-emitting components ( 3 . 5 ) is assigned to the mechanical deformation in each case a deformation unit. Lighting device ( 1 ) according to claim 1, comprising - at least one further organic light-emitting component ( 5 ), which is formed mechanically flexible deformable, wherein the deformation unit ( 7 ) a plurality of organic light-emitting components ( 3 . 5 ) is assigned to the mechanical deformation. Lighting device ( 1 ) according to one of the preceding claims, in which - the organic light-emitting component ( 3 ) a plurality of separately operable light-emitting segments ( 3a . 3b . 3c . 3d . 3e . 3f ) having. Lighting device ( 1 ) according to one of the preceding claims, in which - the organic light-emitting component ( 3 ) is mechanically fixed at least in places on at least one holder element, and - the deformation unit ( 7 ) is formed to a displacement and / or deformation of the at least one holder element, such that the organic light-emitting component ( 3 ) is mechanically deformed. Lighting device ( 1 ) according to one of the preceding claims, comprising a housing in which the organic light-emitting component ( 3 ) and the deformation unit ( 7 ), wherein - the organic light-emitting component ( 3 ) is fixed at least in places fixed relative to the housing, and - the deformation unit ( 7 ) to a displacement and / or deformation of at least a portion of the organic light-emitting component ( 3 ) is formed relative to the housing, such that the organic light-emitting component ( 3 ) is mechanically deformed. Lighting device ( 1 ) according to one of the preceding claims, in which - the organic light-emitting component ( 3 ) comprises a carrier which is magnetically formed, and - the deformation unit ( 7 ) is formed to a displacement and / or deformation of the carrier, such that the organic light-emitting component ( 3 ) is mechanically deformed. Lighting device ( 1 ) according to one of the preceding claims, in which - the deformation unit ( 7 ) as a displacing and / or deforming actuator comprises at least one of: electric motor, electromagnet, hydraulically operated actuator, pneumatically operated actuator, piezoelectrically operated actuator. Method for operating a lighting device ( 1 ) for a vehicle, in which - an input signal is provided which is representative of an operating mode of the vehicle, and - a control signal is determined as a function of the input signal and a deformation unit ( 7 ) of the lighting device ( 1 ), and - an organic light emitting device ( 3 ) of the lighting device ( 1 ) depending on the actuating signal by the deformation unit ( 7 ) is mechanically deformed. Method according to Claim 9, in which - the organic light-emitting component ( 3 ) is mechanically deformed such that a lateral extent of an appearance of the illumination device ( 1 ) is changed. Method according to one of the preceding claims 9 or 10, wherein the organic light-emitting component ( 3 ) a plurality of separately operable light-emitting segments ( 3a . 3b . 3c . 3d . 3e . 3f ), in which - determined depending on the input signal, a further control signal and the organic light emitting device ( 3 ), and a respective light-emitting operation of the light-emitting segments ( 3a . 3b . 3c . 3d . 3e . 3f ) is controlled depending on the further control signal. Method according to one of the preceding claims 9 to 11, in which - mechanical deformation of the organic light-emitting component ( 3 ) is performed steplessly. Method according to one of the preceding claims 9 to 12, in which the illumination device ( 1 ) is formed according to one of the preceding claims 1 to 8. System ( 11 ) for illuminating a vehicle, comprising - a lighting device ( 1 ) with an organic light-emitting component ( 3 ) and a preforming unit ( 7 ), and - a control unit ( 9 ), which is adapted to perform a method according to any one of the preceding claims 9 to 13.

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