DE102015116711A1 - Mobile device with an optical sensor for taking a picture - Google Patents

Abstract

The invention relates to a mobile device, in particular a mobile phone, with an optical sensor, wherein the optical sensor is adapted to receive an image from a receiving area, wherein a light-emitting element is provided for generating light, wherein a light guide is provided, wherein a first portion the light guide is coupled to the luminous element, wherein a second portion of the light guide is guided to a radiation area in order to emit light on the recording area via the emission area.

Description

The invention relates to a mobile device according to claim 1.

In the prior art, mobile phones are known which have an LED as a light-emitting element on a rear side, and an optical sensor for taking an image is provided on the rear side. The luminous element is provided for generating a light radiation during the recording of the image.

The object of the invention is to provide an improved mobile device, with which an image can be taken, wherein a lighting device is provided for providing light for receiving the image.

The object of the invention is achieved by the mobile device according to claim 1.

Further embodiments are given in the dependent claims.

An advantage of the mobile device described is that an increased flexibility in the arrangement of the luminous element is possible independently of a radiation area. This is achieved in that a light guide is provided which directs the light generated by the luminous element to a radiation area of the mobile device. In this way, the light-emitting element can be arranged at a position of the device in which space is available for the light-emitting element. Thus, the design of the mobile device can be reduced. For example, the thickness of the device can be reduced, since the luminous element does not have to be arranged directly behind the emission area, but can be arranged laterally therefrom. The use of the light guide provides reliable conduction of the light from the light element to the emission area.

In one embodiment, a second emission region is provided, wherein the illumination element is arranged on the second emission region in order to emit light over the second emission region. In this way it is possible to provide the light of the luminous element at two different emission areas. In this case, there is a direct light output without a light guide at the second emission area, whereas the light is emitted at the first emission area via the light conductor.

In a further embodiment, a means is provided for guiding the light emitted by the luminous element into the optical waveguide or into the second radiating region. Thus, depending on the desired light output, the light can be emitted either at the first and / or at the second emission area. In this way, on the one hand, the available light can be emitted bundled at a desired emission area. On the other hand, unnecessary light emission is avoided on at least one of the two emission areas. Depending on the selected embodiment, a receiving area for taking a picture may also be provided on the second emitting area.

The means may be designed in the form of a mechanical or electronic diaphragm, wherein the diaphragm is arranged in the beam path between the luminous element and the emission area, in particular between the luminous element and the light conductor. In addition, depending on the selected embodiment, the diaphragm may be provided both in the beam path between the luminous element and the optical waveguide and in the beam path between the luminous element and the second radiating region. Mechanical and electronic diaphragms are reliable means of shielding light.

In a further embodiment, the lighting element is associated with an optical element, in particular a lens for guiding the light, wherein the light guide is coupled to the optical element. By means of the optical element, an improved coupling of the light can be achieved in the light guide.

In a further embodiment, the second emission region is arranged on a first side of the optical element, wherein the optical fiber is coupled to the optical element laterally next to the first side. Thus, both an efficient radiation over the second radiation area and a good coupling into the optical element can be achieved. The lateral coupling of the light guide to the optical element prevents shadowing of the radiated light over the second emission area.

In a further embodiment, the light-emitting element is arranged on a support, wherein an optical element is provided for guiding the light, wherein the support has an opening, wherein the light guide is coupled on a second side of the support to the opening, wherein the optical element is formed is to at least partially guide light from the first side of the carrier over the opening to the light guide. In this case, the emission direction of the luminous element is directed away from the first side of the carrier. In this way, a compact arrangement of the luminous element and the light guide at a low height of the device is possible.

In a further embodiment, the light guide on the first and / or on the second section to an optical element for coupling or for coupling out of light. As a result, an improved coupling or decoupling of the light is achieved. The optical element may be formed for example in the form of a lens. In one embodiment of the device, the luminous element is designed as a light-emitting diode or as a semiconductor laser. Both a light-emitting diode and a semiconductor laser have a sufficient light output for providing light, in particular for providing flash light for recording an image.

In a further embodiment, a second light-emitting element is provided, wherein the input of the light guide is coupled to the second light-emitting element, and wherein the two light-emitting elements emit light with different wavelength spectra. In this way, a desired light color, in particular a desired white light can be generated.

The above-described characteristics, features, and advantages of this invention, as well as the manner in which they are achieved, will become clearer and more clearly understood in connection with the following description of the embodiments which will be described in connection with the drawings

1 a schematic cross-sectional view of an arrangement with a luminous element and with a light guide,

2 a side view of the arrangement of 1 .

3 a schematic cross-sectional view of another arrangement with a luminous element, a light guide and a diaphragm,

4 a side view of the arrangement of 3 .

5 a schematic representation of another arrangement with a luminous element, with a diaphragm, with a light guide and with another panel,

6 a schematic representation of a further arrangement of a luminous element with an optical element,

7 a schematic representation of a first embodiment of a mobile device with a display and an arrangement with a luminous element and a light guide,

8th a schematic representation of another embodiment of a mobile device with a display and an arrangement with a luminous element, and

9 a schematic representation of another embodiment of a mobile device with a luminous element and a light guide shows.

1 shows a schematic representation of a cross section through a first embodiment of a luminous element 1 which is formed in the illustrated embodiment in the form of a light emitting diode. In the illustrated embodiment, a second lighting element 2 provided in the form of a second light-emitting diode. The light-emitting diodes may be formed, for example, in the form of semiconductor chips. In addition, instead of the light-emitting diodes, laser diodes may also be arranged in the form of semiconductor chips.

The lighting elements 1 . 2 are on a first page 3 a carrier 4 arranged. The lighting elements 1 . 2 are trained to light from the first page 3 of the vehicle away from the vehicle 4 leave. Depending on the chosen embodiment, only one light-emitting element can be used 1 be provided. Furthermore, an optical element 5 For example, in the form of a lens or in the form of a reflector provided to that of the lighting elements 1 . 2 emitted light in a radiation area 7 leave. Furthermore, a light guide 8th shown schematically, the to the optical element 5 is coupled.

2 shows a schematic representation of a side view of the arrangement of 1 , In this embodiment, a diaphragm 9 between the optical element 5 and the light guide 8th is provided. The light guide 8th may be in the form of a glass fiber or plastic fiber. The aperture 9 may be in the form of an electrically or mechanically controlled aperture. For example, the aperture 9 be formed in the form of a liquid phase crystal with partially applied electrode, which applies an electromagnetic field depending on a voltage and thus causes a gradual change in the refractive index of the liquid phase crystal. In addition, however, the aperture can 9 be formed in the form of a mechanical diaphragm, wherein the mechanical diaphragm has a cover which is opaque, and between the optical element 5 and the light guide 8th can be pushed to a decoupling of light from the optical element 5 in the light guide 8th to prevent. Thus, in this embodiment, when using the aperture 9 light 6 over the radiating area 7 or additionally via the light guide 8th be delivered. The control of the aperture 9 does not happen over one illustrated electronic circuit above a mechanical lever.

3 shows a further embodiment of the arrangement of 1 , In this embodiment, the optical fiber in the upper region of the optical element 5 is arranged. In addition, the aperture 9 in this embodiment above the light guide 8th between the optical element 5 and the radiating area 7 arranged.

4 shows a schematic side view of the arrangement of 3 , The light guide 8th can both in a first section 10 a first coupling element 12 have better to the light of the light element in the light guide 8th couple. In addition, the light guide 8th Depending on the selected embodiment, at a second portion, in particular at the end of the light guide, a decoupling element 13 in order to decouple the light better, and in particular to extract the light in a desired direction. The coupling element 12 and the decoupling element 13 are formed in the form of optical elements, in particular in the form of lenses or reflectors. For example, domed lenses can be used as optical elements. In addition, or instead of the optical elements reflectors may be provided to redirect the light, in particular to redirect the light by 90 °.

Using the aperture 9 in the emission area 7 can be a blasting of the light of the lighting elements 1 . 2 be prevented. Depending on the selected embodiment can also in the arrangement of the aperture 9 in the emission area 7 the light guide 8th laterally to the optical element 5 be coupled, as in 2 is shown. In addition, depending on the chosen embodiment both in the emission area 7 as well as in the entrance area of the light guide 8th be provided a diaphragm, as schematically with reference to 5 is shown.

5 shows an embodiment of an arrangement with a luminous element 1 . 2 with a panel 9 in the emission area 12 and with a second aperture 14 between the optical element 5 and the light guide 8th , In addition, depending on the selected embodiment, the second aperture 14 on the second section 11 be arranged at the end of the light guide. In this embodiment, the emission of light can be both via the light guide 8th as well as over the radiating area 7 using the irises 9 . 14 be prevented.

6 shows in a schematic cross section a further embodiment of an arrangement in which two lighting elements 1 . 2 on a first page 3 of the carrier 4 are arranged. Depending on the selected embodiment, only one light-emitting element can be provided. In addition, the carrier points 4 an opening 15 on. About the first page 3 of the carrier 1 is a second optical element 16 intended. The second optical element 16 is designed in such a way that light 6 the lighting elements 1 . 2 partly over the radiation area 7 is discharged and partially into the opening 15 is backblasted. The light guide 8th is about a second page 31 of the carrier 4 to the opening 15 coupled. For this purpose, for example, a coupling element 12 in the form of a lens, in particular in the form of a dome lens at the end of the light guide 8th intended. In addition, in the illustrated embodiment, a second aperture 14 between opening 15 and the light guide 8th arranged. Likewise, after the second optical element 16 a panel 9 in the emission area 7 arranged. The second optical element 16 is formed in the form of a lens structure to the light 6 partially pass in the desired manner and partially in the opening 15 redirect. The optical element 16 can do so on a top 17 deflection structures 18 For example, in the form of recesses, which have a corresponding reflection of a portion of the light 6 the lighting elements 1 . 2 in the opening 15 directs. The other part of the light 6 is over the radiating area 7 delivered to the top. Depending on the chosen embodiment may be on the deflecting structures 18 be omitted and the second optical element 16 be provided with scattering particles, so that light 6 partly in the direction of the opening 15 is scattered back. With this arrangement, a low Bauhform is achieved.

The 7 to 9 show different applications of the arrangement of 1 to 6 in a device 19 , In the following embodiments, the embodiments of the 1 to 6 no longer shown in detail, but only with representation of the light element 1 indicated. In each of the devices 19 of the 7 to 9 can one of the embodiments of 1 to 6 be arranged.

7 shows a schematic representation of a mobile device 19 , which is designed for example in the form of a mobile phone or a tablet PC or in the form of a camera. The mobile device 19 has a first page 20 and a second page 21 on. The first and the second page 20 . 21 can be arranged in different directions. For example, the two sides 20 . 21 be formed by 90 ° or 180 ° in the form of a front and a back. The device 19 has an arrangement according to one of 1 to 6 in which, in the illustrated embodiment, the at least one luminous element 1 in the area of the back 21 is arranged. A housing 35 of the device 19 points to the back 21 a lighting aperture 22 up, over the light 6 of the luminous element 1 can be radiated. The light element 1 is with a control unit 23 connected to the lighting element 1 for emitting light. Continue on the second page 21 an optical sensor 24 provided to take a picture of a receiving area in front of the back. The optical sensor 24 stands with the control unit 23 and is used to take pictures according to the control unit 23 driven. Furthermore, the control unit 23 in the provision of apertures in conjunction with the controllable apertures, in order to control the apertures depending on the desired illumination.

Furthermore, the light guide 10 from the luminous element 1 on the first page 20 , which represents a front, to a second radiation area 25 guided. The second radiation area is through an opening in the housing 35 realized. Thus, over the light guide 10 over the second emission area 25 light 6 be delivered on the front. Continue on the first page 20 a second optical sensor 26 provided to take a picture of a receiving area in front of the front. This is the second optical sensor 26 with the control unit 23 in connection. Thus, for example, in the training of the device 19 in the form of a mobile phone on the first page 20 a display 27 be designed to display information. With the in 7 illustrated embodiment may both on the first page 20 as well as on the second page 21 a picture being taken, with both the radiating area 7 on the second page 21 as well as the second emission area 25 on the first page 20 with light from the luminous element 1 can be supplied.

Depending on the chosen embodiment, the light guide 10 or a second light guide 28 that is attached to the light element 1 is coupled to a third radiation area 29 be guided. The third emission area 29 may be arranged in such a way that the third emission area 29 a backlight for the display 27 provides.

8th shows a further embodiment in which only one light guide 10 to the light element 1 is coupled. The light element 1 is trained to be like in 7 Light over the emission area 7 on the second page 21 to capture an image using the optical sensor 24 provide. The light guide 10 is in this embodiment to the display 27 guided. the display 27 is on the first page 20 of the device. The light guide 10 is with a third emission area 29 connected, the light in the form of a backlight for the display 27 provides. The control unit 23 is associated with the aperture when providing apertures, depending on the selected exposure light of the luminous element 1 over the first and / or the third radiation area 7 . 29 leave.

9 shows a further embodiment of a device 19 in which an arrangement according to the 1 to 6 is provided, wherein a light guide 10 to the light element 1 is coupled to light to a second emission area 25 to steer. In the illustrated embodiment, the second radiation area 25 on a third page 30 of the device. Depending on the chosen embodiment, the second radiation area 25 also on another side of the device 19 be arranged. Moreover, on the third page 30 an optical sensor 24 intended. The optical sensor represents a photosensor for taking an image. The light-emitting element 1 and the optical sensor 24 be from the control unit 23 driven. The light element 1 is in the illustrated embodiment spaced from the second radiation area 25 arranged. Due to the light guide 10 can be an available space in the device 19 for the arrangement of the luminous element 1 or for the arrangement of an arrangement according to the 1 to 6 to get voted. Thus, it is not necessary that in the vicinity of the second radiation area 25 Space for the arrangement of 1 to 6 or for the arrangement of a luminous element 1 is available.

Using the described arrangements, for example, an LED can be provided as a light element for a frontflash of a mobile phone to take a selfie, wherein additionally the LED are used as a main flash for taking an image on the back of the mobile phone. Using the proposed arrangements, an available space of a device can be optimally utilized. When using a light element for a Mainflash and a frontflash of a mobile phone both space and a corresponding wiring of a second LED can be saved. Furthermore, the light guide in the second section, that is on an output side, have a directional optics. Thus, no further optics on the device is required. Furthermore, the exposure emitted by the light guide can be used for applications requiring lower brightness.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

1

 light element

2

 second light-emitting element

3

 first page carrier

4

 carrier

5

 optical element

6

 light

7

 radiation area

8th

 optical fiber

9

 cover

10

 first section of optical fiber

11

 second section optical fiber

12

 coupling element

13

 outcoupling

14

 second aperture

15

 opening

16

 second optical element

17

 top

18

 redirecting

19

 device

20

 first page

21

 second page

22

 lighting opening

23

 control unit

24

 Optical sensor

25

 second emission area

26

 second optical sensor

27

 display

28

 second light guide

29

 third emission area

30

 third page

31

 second side carrier

35

 casing

Claims (12)

Mobile device ( 19 ), in particular a mobile telephone, with an optical sensor ( 24 . 26 ), wherein the optical sensor ( 24 . 26 ) is adapted to receive an image of a receiving area, wherein a lighting element ( 1 . 2 ) is provided for generating light, wherein a light guide ( 10 . 28 ), a first section ( 10 ) of the light guide ( 10 . 28 ) to the light element ( 1 . 2 ), wherein a second section ( 11 ) of the light guide ( 10 . 28 ) to a radiation area ( 25 ) is guided over the radiation area ( 25 ) Light ( 6 ) to the receiving area. Apparatus according to claim 1, wherein the luminous element ( 1 . 2 ) at a further radiation area ( 7 ) and wherein light ( 6 ) of the luminous element ( 1 . 2 ) over the further radiation area ( 7 ) can be delivered. Apparatus according to claim 2, wherein an agent ( 9 ) is provided to the light from the element ( 1 . 2 ) emitted light ( 6 ) in the light guide ( 10 ) or in the further radiation area ( 7 ) respectively. Apparatus according to claim 3, wherein the means is in the form of a controllable diaphragm ( 9 ) is formed, wherein the aperture ( 9 ) in the beam path between the luminous element ( 1 . 2 ) and the radiation area ( 25 ), in particular between the lighting element ( 1 . 2 ) and the light guide ( 10 . 20 ) is arranged. Apparatus according to claim 4, wherein the diaphragm ( 9 ) between the luminous element ( 1 . 2 ) and the further radiation area ( 7 ) is arranged. Device according to one of the preceding claims, wherein the luminous element ( 1 . 2 ) an optical element ( 5 ) is assigned to guide the light, and wherein the light guide ( 10 . 28 ) to the optical element ( 5 ), wherein the optical element ( 5 ) is formed in particular in the form of a lens. Device according to one of claims 2 to 5, wherein the luminous element ( 1 . 2 ) an optical element ( 5 ) for guiding the light ( 6 ), and wherein the optical fiber ( 10 ) to the optical element ( 5 ), wherein the optical element ( 5 ) is formed in particular in the form of a lens, wherein the further radiation area ( 7 ) on a first side of the optical element ( 5 ) is formed, and wherein the optical fiber ( 10 ) laterally adjacent to the first side to the optical element ( 5 ) is coupled. Device according to one of the preceding claims, wherein the device ( 19 ) on a first page ( 20 ) a display ( 27 ), wherein the radiation area ( 25 . 29 ) on the first page ( 20 ), and wherein the further radiation area ( 7 ) on a second page ( 21 ) and in particular the second side ( 21 ) is opposite the first side. Device according to one of the preceding claims, wherein the luminous element ( 1 . 2 ) on a first page ( 3 ) of a carrier ( 4 ), wherein an optical element ( 16 ) is provided for guiding the light, wherein the carrier ( 4 ) an opening ( 15 ), wherein the optical fiber ( 10 ) on a second page ( 31 ) of the carrier ( 4 ) to the opening ( 15 ), wherein the optical element ( 16 ) is adapted to light ( 6 ) at least partially into the opening ( 15 ) to the light guide ( 10 ) to steer. Device according to one of the preceding claims, wherein the light guide ( 10 ) on a first section ( 10 ) and / or at a second section ( 11 ) an optical element ( 12 . 13 ) for coupling or for coupling out of light. Device according to one of the preceding claims, wherein the luminous element ( 1 . 2 ) is designed as a light-emitting diode or as a semiconductor laser. Device according to one of the preceding claims, wherein a second luminous element ( 2 ) is provided, wherein the optical fiber ( 10 ) to the second light-emitting element ( 2 ), and wherein the two light elements ( 1 . 2 ) Generate light with different wavelength spectra.

Images