CN112393691A - Light emitting module, depth camera and electronic equipment - Google Patents

Abstract

The application discloses optical transmission module, degree of depth camera and electronic equipment. The light emitting module includes a light source, a reflective element and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The reflecting surface of the reflecting element is opposite to the light emitting surface of the light source, and the reflecting element is used for reflecting the light signal. The diffuser is used for diffusing the optical signal reflected by the reflecting element. The light emitting module, the depth camera and the electronic device of the embodiment of the application use a light source capable of emitting optical signals with the wavelength of 1350 nm-1550 nm and use a photosensitive element capable of only receiving the optical signals with the wavelength of 1350 nm-1550 nm. Because the ambient light almost does not have the background light signal with the wavelength of 1350 nm-1550 nm, the influence of the background light signal on the calculation of the moment when the light receiving module receives the light signal is avoided, and the acquisition precision of the depth information can be further improved.

Description

Light emitting module, depth camera and electronic equipment

Technical Field

The application relates to the technical field of three-dimensional imaging, in particular to a light emitting module, a depth camera and an electronic device.

Background

Time of Flight (TOF) depth cameras have been widely used in electronic devices such as mobile phones, so that the electronic devices have a function of acquiring three-dimensional information of an object. The time-of-flight depth camera can calculate the depth information of the measured object by calculating the time difference between the moment when the light emitting module emits the light signal and the moment when the light receiving module receives the light signal. The wavelength band of the optical signal emitted by the current optical transmission module is usually 850nm or 940 nm. Under outdoor highlight environment, there is 850nm or 940 nm's light in the ambient light, and this part light also can be received by the optical receiving module, and this can lead to the moment that optical signal was received to the optical receiving module to calculate the mistake, further influences the acquisition precision of depth information.

Disclosure of Invention

The embodiment of the application provides a light emission module, a depth camera and an electronic device.

The light emitting module of the present embodiment includes a light source, a reflective element and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The reflecting surface of the reflecting element is opposite to the light emitting surface of the light source, and the reflecting element is used for reflecting the optical signal. The diffuser is used for diffusing the optical signal reflected by the reflecting element.

The light emitting module of the embodiment of the present application includes a light source and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The light emitting surface of the light source faces the diffuser, and the diffuser is used for diffusing the optical signal.

The depth camera of the embodiment of the application comprises a light emitting module and a light receiving module. The light emitting module includes a light source, a reflective element and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The reflecting surface of the reflecting element is opposite to the light emitting surface of the light source, and the reflecting element is used for reflecting the optical signal. The diffuser is used for diffusing the optical signal reflected by the reflecting element. The optical receiving module is used for receiving the optical signal which is emitted by the optical emitting module and reflected.

The depth camera of the embodiment of the application comprises a light emitting module and a light receiving module. The light emitting module includes a light source and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The light emitting surface of the light source faces the diffuser, and the diffuser is used for diffusing the optical signal. The optical receiving module is used for receiving the optical signal which is emitted by the optical emitting module and reflected.

The electronic device of the embodiment of the application comprises a shell and a depth camera. The depth camera is coupled to the housing. The depth camera comprises a light emitting module and a light receiving module. The light emitting module includes a light source, a reflective element and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The reflecting surface of the reflecting element is opposite to the light emitting surface of the light source, and the reflecting element is used for reflecting the optical signal. The diffuser is used for diffusing the optical signal reflected by the reflecting element. The optical receiving module is used for receiving the optical signal which is emitted by the optical emitting module and reflected.

The electronic device of the embodiment of the application comprises a shell and a depth camera. The depth camera is coupled to the housing. The depth camera comprises a light emitting module and a light receiving module. The light emitting module includes a light source and a diffuser. The light source is used for emitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm. The light emitting surface of the light source faces the diffuser, and the diffuser is used for diffusing the optical signal. The optical receiving module is used for receiving the optical signal which is emitted by the optical emitting module and reflected.

The light emitting module, the depth camera and the electronic device of the embodiment of the application use a light source capable of emitting optical signals with the wavelength of 1350 nm-1550 nm and use a photosensitive element capable of only receiving the optical signals with the wavelength of 1350 nm-1550 nm. Because the ambient light almost does not have the background light signal with the wavelength of 1350 nm-1550 nm, the influence of the background light signal on the calculation of the moment when the light receiving module receives the light signal is avoided, and the acquisition precision of the depth information can be further improved.

Additional aspects and advantages of embodiments of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the present application.

Drawings

The above and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic plan view of an electronic device according to an embodiment of the present application;

FIG. 2 is a perspective assembly view of a depth camera according to an embodiment of the present application;

FIG. 3 is a plan view assembly schematic of a depth camera of an embodiment of the present application;

FIG. 4 is a schematic cross-sectional view of one embodiment of the depth camera shown in FIG. 3 along line IV-IV;

FIG. 5 is a schematic cross-sectional view of another embodiment of the depth camera shown in FIG. 3 along line IV-IV;

FIG. 6 is a plan view assembly schematic of a depth camera of an embodiment of the present application;

FIGS. 7 and 8 are exploded perspective views of the depth camera of FIG. 4;

FIGS. 9 and 10 are exploded perspective views of the pad assembly and the light emitting module of the depth camera shown in FIG. 4;

FIG. 11 is a schematic plan view of the light receiving module shown in FIG. 4;

FIG. 12 is a schematic plan view of the light receiving module shown in FIG. 5;

FIG. 13 is a schematic perspective view of a light source 31 according to some embodiments of the present application;

FIG. 14 is a schematic view of a diffuser of a light receiving module according to some embodiments of the present disclosure;

fig. 15 is a schematic diagram of the power of the optical signal output by the optical transmit module according to some embodiments of the present disclosure.

Description of the main elements and symbols:

electronic device 1000, chassis 200, front surface 201, back surface 202, visible light camera 300, display screen 400, depth camera 100, substrate 10, flexible circuit board 11, reinforcing plate 12, gasket component 20, gasket 21, first surface 211, second surface 212, conductive hole 213, thermal conductive hole 214, conductive member 22, thermal conductive member 23, light emitting module 30, light source 31, light emitting surface 310, lower layer N-type electrode 311, N-type indium phosphide substrate 312, N-type confinement layer 313, N-type waveguide layer 314, multi-quantum well active region 315, P-type waveguide layer 316, P-type confinement layer 317, upper layer P-type electrode 318, support 32, mounting space 321, light outlet 322, diffuser 33, light inlet surface 331, light outlet surface 332, non-plated region 333, plated region, photodetector 34, glue 35, high reflection film 36, filter film 37, reflection element 38, reflection surface 381, conductive wire 39, light receiving module 40, lens barrel 41, lens barrel 334, light source, light emitting device, and light emitting device, The light inlet 411, the light sensing element 42, the lens assembly 43, the optical filter 44, the housing 50, the first receiving cavity 51, the second receiving cavity 52, the mounting groove 53, the first sub-housing 54, the light passing port 541, the second sub-housing 55, the connector 60, and the processor 70.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative and are only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

Referring to fig. 3, 4 and 11, a light emitting module 30 is provided. The light emitting module 30 includes a light source 31, a reflective element 38, and a diffuser 33. The light source 31 is used for emitting optical signals, wherein the wavelength of the optical signals is 1350nm to 1550 nm. The reflection surface 381 of the reflection element 38 faces the light emitting surface 310 of the light source, and the reflection element 38 is used to reflect the optical signal. The diffuser 33 is used for diffusing the optical signal reflected by the reflective element 38.

Referring to fig. 3, 5 and 12, the present application further provides a light emitting module 30. The light emitting module 30 includes a light source 31 and a diffuser 33. The light emitting surface 310 of the light source 31 faces the diffuser 33. The light source 31 is used for emitting optical signals, wherein the wavelength of the optical signals is 1350nm to 1550 nm. The diffuser 33 serves to diffuse the optical signal emitted by the light source 31.

Referring to fig. 3, 4 and 5, the present application further provides a light receiving module 40. The light receiving module 40 includes a lens assembly 43 and a photosensitive element 42. The photosensitive element 42 is used for receiving only the optical signal which passes through the lens assembly 43 and has the waveband of 1350nm to 1550 nm.

Referring to fig. 3, 4 and 11, the present application further provides a depth camera 100. The depth camera 100 includes a light emitting module 30 and a light receiving module 40. The light emitting module 30 includes a light source 31, a reflective element 38, and a diffuser 33. The light source 31 is used for emitting optical signals, wherein the wavelength of the optical signals is 1350nm to 1550 nm. The reflection surface 381 of the reflection element 38 faces the light emitting surface 310 of the light source, and the reflection element 38 is used to reflect the optical signal. The diffuser 33 is used for diffusing the optical signal reflected by the reflective element 38. The light receiving module 40 includes a lens assembly 43 and a photosensitive element 42. The photosensitive element 42 is used for receiving only the optical signal which passes through the lens assembly 43 and has the waveband of 1350nm to 1550 nm.

Referring to fig. 3, 5 and 12, the present application further provides a depth camera 100. The depth camera 100 includes a light emitting module 30 and a light receiving module 40. The light emitting module 30 includes a light source 31 and a diffuser 33. The light emitting surface 310 of the light source 31 faces the diffuser 33. The light source 31 is used for emitting optical signals, wherein the wavelength of the optical signals is 1350nm to 1550 nm. The diffuser 33 serves to diffuse the optical signal emitted by the light 31. The light receiving module 40 includes a lens assembly 43 and a photosensitive element 42. The photosensitive element 42 is used for receiving only the optical signal which passes through the lens assembly 43 and has the waveband of 1350nm to 1550 nm.

Referring to fig. 1, fig. 4, and fig. 11, the present application further provides an electronic device 1000. The electronic device 1000 includes a housing 200 and a depth camera 100. The depth camera 100 includes a light emitting module 30 and a light receiving module 40. The light emitting module 30 includes a light source 31, a reflective element 38, and a diffuser 33. The light source 31 is used for emitting optical signals, wherein the wavelength of the optical signals is 1350nm to 1550 nm. The reflection surface 381 of the reflection element 38 faces the light emitting surface 310 of the light source, and the reflection element 38 is used to reflect the optical signal. The diffuser 33 is used for diffusing the optical signal reflected by the reflective element 38. The light receiving module 40 includes a lens assembly 43 and a photosensitive element 42. The photosensitive element 42 is used for receiving only the optical signal which passes through the lens assembly 43 and has the waveband of 1350nm to 1550 nm.

Referring to fig. 1, fig. 5 and fig. 12, the present application further provides an electronic device 1000. The electronic device 1000 includes a housing 200 and a depth camera 100. The depth camera 100 includes a light emitting module 30 and a light receiving module 40. The light emitting module 30 includes a light source 31 and a diffuser 33. The light emitting surface 310 of the light source 31 faces the diffuser 33. The light source 31 is used for emitting optical signals, wherein the wavelength of the optical signals is 1350nm to 1550 nm. The diffuser 33 serves to diffuse the optical signal emitted by the light 31. The light receiving module 40 includes a lens assembly 43 and a photosensitive element 42. The photosensitive element 42 is used for receiving only the optical signal which passes through the lens assembly 43 and has the waveband of 1350nm to 1550 nm.

In a depth camera that acquires depth information of an object to be measured based on a Time of Flight (TOF) technique, a wavelength band of an optical signal emitted by an optical emission module is usually 850nm or 940 nm. Ambient light also exists in the wavelength band of 850nm or 940 nm. When the depth camera works in an outdoor environment, the light receiving module receives light signals emitted by the light emitting module and also receives light (namely background light signals) with a waveband of 850nm or 940nm in the ambient light, the background light signals influence the calculation of the time when the light receiving module receives the light signals, and the calculation error of the time when the light receiving module receives the light signals influences the acquisition precision of the depth information.

The light emitting module 30, the light receiving module 40, the depth camera 100 and the electronic device 1000 according to the embodiment of the present application use the light source 31 that can emit the optical signal having the wavelength of 1350nm to 1550nm, and use the photosensitive element 42 that can receive only the optical signal having the wavelength of 1350nm to 1550 nm. Because there is almost no light (i.e. background light signal) with a wavelength of 1350nm to 1550nm in the ambient light, even in an outdoor strong light environment, the background light signal with a wavelength of 1350nm to 1550nm is still very small, and the influence of the very small background light signal on the calculation of the time when the light receiving module 40 receives the light signal is very small, and the accuracy of the depth information calculated according to the time when the light receiving module 40 receives the light signal is relatively high. The optical signal with a wavelength band of 1350nm to 1550nm refers to: the wavelength of the optical signal may be any one of 1350nm, 1360nm, 1370nm, 1385nm, 1394nm, 1400nm, 1410nm, 1425nm, 1450nm, 1480nm, 1490nm, 1500nm, 1520nm, 1535nm, 1540nm, 1550nm, or any value in between.

Referring to fig. 1, an electronic device 1000 according to an embodiment of the present disclosure includes a housing 200 and a depth camera 100. The electronic device 1000 may be a mobile phone, a tablet computer, a smart watch, a smart bracelet, a smart helmet, smart glasses, a head display device, a game machine, a notebook computer, etc., and the application takes the electronic device 1000 as a mobile phone as an example for description, and it is understood that the specific form of the electronic device 1000 is not limited to the mobile phone.

The chassis 200 may serve as a mounting carrier for functional elements of the electronic device 1000, the chassis 200 may provide protection for the functional elements, such as dust prevention, water prevention, and falling prevention, and the functional elements may be elements of the display screen 400, the visible light camera 300, the depth camera 100, a main board, and a power supply module of the electronic device 1000. The chassis 200 may include a front 201 and a back 202, the front 201 is opposite to the back 202, and the functional elements may be mounted on the front 201 or the back 202. For example, as shown in fig. 1, the display screen 400 is installed on the front side 201, the visible light camera 300 is installed on the back side 202, and the depth camera 100 is installed on the back side 202, in which case, the visible light camera 300 can be used as a rear camera, and the depth camera 100 can also be used as a rear depth camera. Among other things, the visible light camera 300 may include one or more of a tele camera, a wide camera, a periscopic camera, a black and white camera, etc.; the display screen 400 may be a liquid crystal display screen, an OLED display screen, a Micro led display screen, or the like.

Of course, in other embodiments, the installation positions of the display screen 400, the visible light camera 300, and the depth camera 100 on the chassis 200 may be arranged in other manners, for example, the display screen 400 may be arranged on the front 201 and the back 202 at the same time, the visible light camera 300 may also be arranged on the front 201 to serve as a front camera, the depth camera 100 may also be arranged on the front 201 to serve as a front depth camera, in addition, the visible light camera 300 may also be arranged below the display screen 400, that is, the visible light camera 300 receives light passing through the display screen 400 for imaging, the depth camera 100 may also be arranged below the display screen 400, an optical signal emitted by the depth camera 100 enters the outside of the electronic device 1000 after passing through the display screen 400, and the depth camera 100 receives an optical signal passing through the display screen 400 from the outside of the electronic device 1000 to obtain depth information.

Referring to fig. 1 to 4, the depth camera 100 includes a substrate 10, a housing 50, a pad assembly 20, a light emitting module 30, a light receiving module 40, and a processor 70. Among other things, depth camera 100 may be a time-of-flight depth camera that acquires depth information using the principles of time-of-flight ranging.

Referring to fig. 2 to 4, the substrate 10 may be used to support a housing 50, a pad assembly 20, a light emitting module 30 and a light receiving module 40. The substrate 10 may be used to electrically connect a main board of the electronic device 1000 with the pad assembly 20, the light emitting module 30 and the light receiving module 40. The substrate 10 includes a flexible circuit board 11 and a reinforcing plate 12. The flexible circuit board 11 is laid with a circuit, the pad assembly 20 and the light receiving module 40 can be disposed on one side of the flexible circuit board 11, and the circuit is electrically connected to the pad assembly 20, the light emitting module 30 and the light receiving module 40. The reinforcing plate 12 may be disposed on the other side of the flexible circuit board 11, and the reinforcing plate 12 may be made of a material having a relatively large hardness, such as steel, to improve the overall strength of the substrate 10 and facilitate the electrical connection of the circuit with the pad module 20 and the optical receiving module 40.

Referring to fig. 3 and 4, the housing 50 is disposed on the substrate 10, and the housing 50 may be connected to the substrate 10, for example, the housing 50 is adhered to the substrate 10 by glue. The housing 50 may be used to form a portion of the housing of the depth camera 100, and the pad assembly 20, the light emitting module 30, and the light receiving module 40 may be at least partially housed within the housing 50.

The housing 50 may be a one-piece unitary body. The housing 50 may have a plurality of cavities, and different cavities may be used to accommodate different components of the pad module 20, the light emitting module 30, and the light receiving module 40. The housing 50 and the substrate 10 enclose a first receiving cavity 51 and a second receiving cavity 52, the first receiving cavity 51 may be spaced apart from the second receiving cavity 52, and the first receiving cavity 51 may also be communicated with the second receiving cavity 52.

In the embodiment of the present application, the housing 50 includes a first sub-housing 54 and a second sub-housing 55, and the first sub-housing 54 and the second sub-housing 55 can be manufactured by an integral molding process, for example, by forming the first sub-housing 54 and the second sub-housing 55 by one-time casting, or forming the first sub-housing 54 and the second sub-housing 55 by one-time cutting. The first sub-housing 54 and the substrate 10 together form a first receiving cavity 51, the first sub-housing 54 forms a light-passing opening 541, the light-passing opening 541 is communicated with the first receiving cavity 51, and the second sub-housing 55 and the substrate 10 together form a second receiving cavity 52.

In another example, the housing 50 includes a plurality of sub-housings separately arranged, each sub-housing can be separately connected to the substrate 10, for example, one sub-housing is used for accommodating the light emitting module 30, and the other sub-housing is used for accommodating the light receiving module 40, the two sub-housings can be respectively adhered to the substrate 10 by glue, and when one of the devices (which may be the light emitting module 30 or the light receiving module 40) needs to be repaired or replaced, one of the sub-housings can be disassembled without affecting the other sub-housing and the other device.

Referring to fig. 4, 9 and 10, the pad assembly 20 is disposed on the substrate 10. The pad assembly 20 is electrically connected to the substrate 10. The pad assembly 20 includes a pad 21 and a conductive member 22.

The pad 21 is disposed on the substrate 10, and the relative position between the pad 21 and the substrate 10 may be fixed, for example, by bonding the pad 21 to the substrate 10. The spacer 21 may be accommodated in the first accommodation cavity 51 to prevent the spacer 21 from falling off the substrate 10 and falling out, but the spacer 21 may not be accommodated in the housing 50. The spacer 21 may be insulating, for example the spacer 21 may be a PCB board, a ceramic block, etc. The spacer 21 includes a first surface 211 and a second surface 212, wherein the first surface 211 is opposite to the second surface 212. When the cushion block 21 is arranged on the substrate 10, the first surface 211 is carried on the substrate 10, and the second surface 212 and the substrate 10 form a certain height difference, so that the elements arranged on the second surface 212 are raised relative to the substrate 10 compared with the elements directly arranged on the substrate 10, and the arrangement requirements of different elements on the height can be met by selecting cushion blocks 21 with different heights. The pad 21 has a conductive hole 213, and the conductive hole 213 penetrates the first surface 211 and the second surface 212. The conductive hole 213 may be formed in a position spaced apart from the outer peripheral wall of the spacer 21, and the conductive hole 213 may be formed in the outer peripheral wall of the spacer 21.

The conductive member 22 is disposed in the conductive hole 213. The conductive device 22 may be any conductive material such as conductive silver paste, conductive ceramic, etc., and the conductive device 22 may be filled in the conductive hole 213 and exposed from the first surface 211 and the second surface 212. The portion of the conductive member 22 exposed from the first side 211 may be used to electrically connect with the substrate 10, and the portion of the conductive member 22 exposed from the second side 212 may be used to electrically connect with a component (e.g., the light source 31 and/or the light detector 34) disposed on the second side 212, such that the conductive member 22 is used to electrically connect the component with the substrate 10. The number of the conductive vias 213 and the positions of the conductive vias 213 can be arbitrarily set according to the wiring requirements of the components disposed on the second surface 212, and are not limited to the examples shown in the drawings of the present application.

Referring to fig. 2 and 4, the light emitting module 30 is disposed on the second surface 212, the light emitting module 30 is electrically connected to the substrate 10 through the conductive member 22, and the light receiving module 40 is disposed on the substrate 10. It can be understood that since the first surface 211 is combined with the substrate 10 and the light receiving module 40 is disposed on the substrate 10, the light receiving module 40 and the first surface 211 are disposed at substantially the same height with respect to the substrate 10, and at the same time, the second pad 21 has a certain thickness, that is, the second surface 212 and the first surface 211 have a certain height difference, so that the light emitting module 30 is disposed at a height (the same below with respect to the substrate 10) higher than the light receiving module 40 (the same below with respect to the substrate 10). Because the height of the light emitting module 30 is smaller than the height of the light receiving module 40, the height of the light emitting module 30 is higher than the height of the light receiving module 40, so that the light receiving module 40 can be prevented from shielding the light emitting module 30 to emit light signals, the light emitting end of the light emitting module 30 is closer to the light incident end of the light receiving module 40, and the depth information obtained by the depth camera 100 is complete.

Referring to fig. 4, 9 to 11, the light emitting module 30 is disposed on the second surface 212. In the embodiment of the present application, the light emitting module 30 and the pad 21 are both accommodated in the first accommodating cavity 51. The light emitting module 30 includes a light source 31, a support 32, a reflective element 38, a diffuser 33(diffuser), a photo-detector 34, a high reflective film 36, and a filter 37.

The bracket 32 is disposed on the second face 212. The bracket 32 may be adhered to the second surface 212 by an adhesive 35, the bracket 32 and the second surface 212 together define a mounting space 321, and the mounting space 321 may be used for disposing the light source 31. The bracket 32 may further have a light outlet 322, the light outlet 322 is communicated with the installation space 321, and the light outlet 322 may be used for light emitted by the light source 31 to pass through.

The reflective element 38 is received in the mounting space 321, and for example, the reflective element 38 may be disposed on the second face 212, and the reflective element 38 may be disposed on the second face 212 by gluing. The reflective element 38 may be made of quartz or the like. The reflective surface 381 of the reflective element 38 may be plated with a highly reflective material such as gold, silver, aluminum, copper, etc. to enhance the reflectivity of the reflective element 38.

The light source 31 is accommodated in the mounting space 321, and the light emitting surface 310 of the light source 31 faces the reflection surface 381 of the reflection element 38. The distance between the light source 31 and the reflective element 38 may be within 0.04mm to 0.06 mm. Illustratively, the distance between the light source 31 and the reflective element 38 may be 0.04mm, 0.042mm, 0.045mm, 0.048mm, 0.05mm, 0.053mm, 0.055mm, 0.057mm, 0.06mm, etc. When the distance between the light source 31 and the reflecting member 38 is less than 0.04mm, the light source 31 and the reflecting member 38 are too close to each other, and the light source 31 and the reflecting member 38 are likely to collide with each other when they are mounted. When the distance between the light source 31 and the reflecting element 38 is greater than 0.06mm, the light source 31 is too far away from the reflecting element 38, which may increase loss of the light signal emitted by the light source 31, cause the power of the light signal finally emitted to the outside to be too low, and further affect the accuracy of obtaining the depth information.

The light source 31 may be a Vertical Cavity Surface Emitting Laser (VCSEL) or an Edge Emitting Laser (EEL). The light source 31 can emit light signals with uniform light spots outwards, and the wavelength of the light signals is 1350nm to 1550 nm. The optical signal is reflected by the reflecting surface 381 of the reflecting element 38 and passes through the light outlet 322 to reach the diffuser 33. The light source 31 may be disposed on the second side 212, and the light source 31 may be disposed on the second side 212 by means of gluing. The light source 31 can be electrically connected with the conductive member 22, and the light source 31 is electrically connected with the substrate 10 through the conductive member 22, so that an excessively long or excessively complicated connection circuit is prevented from being used for connecting the light source 31 with the substrate 10, parasitic inductance of the connection circuit is reduced, the light source 31 is favorable for emitting an ideal optical signal, and the accuracy of finally obtained depth information is improved. In one example, the leads of the light source 31 may be directly electrically connected to the conductive member 22 exposed from the second surface 212, and in another example, the light source 31 may be electrically connected to the conductive member 22 by Wire Bonding.

In one embodiment of the present application, the light source 31 is an edge emitting laser. Wherein, the number of the edge-emitting lasers can be one or more. When the number of the edge-emitting lasers is plural, the plural edge-emitting lasers are connected in parallel. Referring to fig. 11 and 13, in one example, the light source 31 includes a lower N-type electrode 311, an indium-phosphide (N-InP) substrate 312, an N-type confinement layer 313, an N-type waveguide layer 314, a multi-quantum-well active region 315, a P-type waveguide layer 316, a P-type confinement layer 317, and an upper P-type electrode 318. In a direction perpendicular to the edge-emitting laser 31 (i.e., the direction indicated by the line a-a), a lower N-type electrode 311, an N-type indium phosphide (N-InP) substrate 312, an N-type confinement layer 313, an N-type waveguide layer 314, a multiple quantum well active region 315, a P-type waveguide layer 316, a P-type confinement layer 317, and an upper P-type electrode 318 are sequentially disposed. There are a plurality of upper P-type electrodes 318, for example, there may be 2, 3, 4, 5, 6, 8, 10, 15, 20, etc. A plurality of upper P-type electrodes 318 are disposed on the P-type confinement layer 317, and two adjacent upper P-type electrodes 318 are disposed at intervals. The plurality of upper P-type electrodes 318 share a lower N-type electrode 311, an N-type indium phosphide (N-InP) substrate 312, an N-type confinement layer 313, an N-type waveguide layer 314, a multiple quantum well active region 315, a P-type waveguide layer 316, and a P-type confinement layer 317, and each of the upper P-type electrodes 318 and the lower N-type electrode 311, the N-type indium phosphide (N-InP) substrate 312, the N-type confinement layer 313, the N-type waveguide layer 314, the multiple quantum well active region 315, the P-type waveguide layer 316, and the P-type confinement layer 317 form an edge emitting laser. Since the power of the optical signal emitted by a single edge-emitting laser is low, the power of the optical signal emitted by the light source 31 can be increased by arranging a plurality of edge-emitting lasers, which is beneficial to improving the accuracy of obtaining the depth information. If the number of the side emitting lasers is plural, when the light source 31 is electrically connected to the conductive member 22 by wire bonding, a plurality of conductive wires 39 may be used to connect the light source 31 to the conductive member 22. In one example, the number of conductive wires 39 is 16, with 8 of the conductive wires 39 connecting the positive pole of the light source 31 and the remaining 8 of the conductive wires 39 connecting the negative pole of the light source 31. Of course, the number of the conductive wires 39 is not limited thereto, the number of the conductive wires 39 may also be 4, 8, 12, 20, 30, 36, 40, and so on, and the specific number of the conductive wires 39 may be determined according to the number of the edge-emitting lasers, and is not limited herein. The plurality of conductive lines 39 may function to share current. It will be appreciated that when the light source 31 is comprised of a plurality of edge-emitting lasers, the operating current required for the light source 31 will also increase. The plurality of conducting wires 39 can share a larger working current, so that the working current borne by each conducting wire 39 is reduced, the conducting wires 39 are prevented from being damaged due to the overlarge working current, and the use reliability of the conducting wires 39 can be improved.

Referring to fig. 4, 9 to 11, the diffuser 33 is disposed on the bracket 32, and specifically, the diffuser 33 may be adhered to the bracket 32 by glue 35. The diffuser 33 includes an incident surface 331 and an emergent surface 332 opposite to each other, wherein the incident surface 331 faces the first surface 211. The diffuser 33 may be made of transparent glass or resin. The diffuser 33 may be located outside the installation space 321, for example, the diffuser 33 may completely cover the light outlet 322, and the light incident surface 331 of the diffuser 33 is abutted against the bracket 32. The light signal emitted from the light source 31 is reflected by the reflection surface 318 and passes through the light outlet 322 to reach the diffuser 33, and the diffuser 33 can increase the range of the viewing angle of the light signal, so that the light signal emitted from the light emitting module 30 can be irradiated to a larger range. The optical signal passing through the diffuser 33 may further pass through the light-passing port 541, and after passing through the light-passing port 541, the optical signal is emitted out of the depth camera 100.

It should be mentioned that, if an opening is needed on the chassis 200 for the optical signal emitted by the optical emission module 30 to pass through, the optical emission module 30 is lifted up, so that the distance between the optical emission module 30 and the opening on the chassis 200 can be reduced, and since the optical signal emitted by the optical emission module 30 is a divergent optical signal, on the premise that the light fluxes of the emergent light beams are the same, the distance between the optical emission module 30 and the opening on the chassis 200 is smaller, the size of the opening can be smaller, the opening is smaller, on the one hand, the influence on the appearance of the electronic device 1000 is smaller, and on the other hand, the screen occupation ratio of the electronic device 1000 can also be enlarged.

The photodetector 34 is disposed on the second face 212 and is located within the mounting space 321. The conductive holes 213 are used for the conductive members 22 to pass through to electrically connect the photodetector 34 and the substrate 10. The number of the photodetectors 34 may be one or more, and when the number of the photodetectors 34 is one, one photodetector 34 corresponds to one conductive hole 213; when the number of the photodetectors 34 is plural, one conductive hole 213 corresponds to each photodetector 34. The photodetector 34 may be used to receive the optical signal reflected by the diffuser 33 to form a detection electrical signal, which may be a current signal, a voltage signal, a power signal calculated from the current signal or the voltage signal, a resistance signal, etc., without limitation. The detection electric signal may be used as a basis for determining whether the light source 31 is in the constant power operation state, may be used as a basis for determining whether the diffuser 33 is in the normal operation state, and may be used as a basis for determining whether the diffuser 33 is in the normal operation state while being used as a basis for determining whether the light source 31 is in the constant power operation state. The light source 31 is in a constant power operation state, which means that the power output by the light source 31 is stabilized at a target power (the target power may be a value or a range, when the target power is a value, the power output by the light source 31 is equal to the target power, and when the target power is a power range, the power output by the light source 31 is within the power range), and if the power output by the light source 31 is not stabilized at a target power, it indicates that the light source 31 is not in the constant power operation state. Of course, the power output by the light source 31 may be required in different application scenarios, such as some application scenarios (e.g. the application scenario in which the depth camera 100 is used as a rear depth camera) that require the power output by the light source 31 to be stabilized at a higher power (one value or a range), for example, that the power output by the light source 31 is stabilized at 10W. Some applications (e.g., applications in which the depth camera 100 is used as a front-facing depth camera) require the power output by the light source 31 to be stabilized at a lower power (one value or a range), for example, require the power output by the light source 31 to be stabilized at 5W-6W. Wherein the target power may be inconsistent for different application scenarios. The diffuser 33 is in a normal operating condition, which means that the diffuser 33 is not damaged (e.g., broken) or removed, and when the diffuser 33 is damaged and/or removed, the diffuser 33 is in an abnormal operating condition.

Specifically, when the light source 31 is in the constant power operation state and the diffuser 33 is in the normal operation state, the light source 31 outputs the optical signal with stable power, the diffuser 33 is intact, the photodetector 34 can receive all the optical signals reflected by the diffuser 33, and the electrical detection signal output by the photodetector 34 is equal to the first electrical signal (i.e. one value) or within the first electrical signal range. Because different application scenarios have different requirements on the power output by the light source 31, the first electrical signal (or the first electrical signal range) is determined according to the target power in different application scenarios, and when the target power is higher, the first electrical signal (or the value in the first electrical signal range) is also higher; when the target power is small, the first electrical signal (or a value in the range of the first electrical signal) is also small. When the light source 31 is not in the constant power operation state and the diffuser 33 is in the normal operation state, the detection electrical signal may be equal to the second electrical signal (i.e., one value) or within a second electrical signal range, wherein when the detection electrical signal is equal to the second electrical signal, the second electrical signal is smaller than the first electrical signal or smaller than the minimum value of the first electrical signal range; when the detected electrical signal is within the second electrical signal range, the maximum value of the second electrical signal range is less than the first electrical signal range or less than the minimum value of the first electrical signal range. The light source 31 is not in the constant power operation state may be caused by a temperature change of the light source 31, and generally, when the temperature of the light source 31 increases, the power output by the light source 31 cannot be stabilized at the target power required by the current application scenario, the power output by the light source 31 decreases, the amount of the optical signal received by the optical detector 34 and reflected by the diffuser 33 decreases, and the output detection electrical signal also decreases. When the diffuser 33 is not in the normal operating state, no matter whether the light source 31 is in the constant power operating state or not, the detection electrical signal is equal to a third electrical signal (i.e., a value) or within a third electrical signal range, wherein when the detection electrical signal is equal to the third electrical signal, the third electrical signal is smaller than the second electrical signal or smaller than the minimum value of the second electrical signal range; when the detected electrical signal is within a third electrical signal range, a maximum value of the third electrical signal range is less than the second electrical signal or less than a minimum value of the second electrical signal range. It is understood that when the diffuser 33 is damaged and/or removed, the reflected optical signal from the diffuser 33 will be greatly reduced, the reflected optical signal received by the optical detector 34 will be greatly reduced, and the output detection electrical signal will be greatly reduced, no matter whether the power of the optical signal output by the light source 31 is stabilized at the target power.

Referring to fig. 11 and 14, the high reflection film 36 is disposed on the diffuser 33. The diffuser 33 includes a coated region 334 and an uncoated region 333 contiguous with the coated region 334. The high-reflection film 36 is formed in a coated area 334, and the coated area 334 corresponds to the light receiving area of the photodetector 34; the non-coated region 334 corresponds to a light signal region where the light source 31 emits a light signal. When the number of the photodetectors 34 is one, the plating region 334 corresponds to a light receiving region of one photodetector 34; when the number of the photodetectors 34 is multiple, the coated region 334 corresponds to the light receiving regions of the photodetectors 34, and for example, the coated region 334 may surround the non-coated region 333, so that the coated region 334 may correspond to the light receiving regions of the photodetectors 34. The high-reflection film 36 is used for reflecting optical signals with the wavelength of 1350-1550 nm. It is understood that when the outdoor ambient light is strong, there may be a small amount of 1350-1550 nm light in the ambient light, and this light may pass through the diffuser 33 and be incident on the photo-detector 34, so that the photo-detector 34 may receive 1350-1550 nm light in the ambient light in addition to the light signal reflected by the diffuser 33. The high reflection film 36 has high reflectivity, and the high reflection film 36 is used to reflect 1350-1550 nm light in ambient light, so as to prevent the 1350-1550 nm light in the ambient light from interfering with the photodetector 34.

The filter film 37 is provided on the photodetector 34. When the number of the photodetectors 34 is one, the filter 37 is also one, and the one filter 37 is disposed on the one photodetector 34; when the number of the photodetectors 34 is plural, the number of the filters 37 is also plural, and one filter 37 is provided for each photodetector 34. The filter 37 may be used to transmit only optical signals having wavelengths of 1350nm to 1550 nm. It will be appreciated that although the highly reflective film 36 is provided, light of ambient light having a wavelength outside of 1350nm to 1550nm may pass through the diffuser 33 to be incident on the light detector 34. The filter 37 is disposed on the photodetector 34 to block light of ambient light having a wavelength other than 1350nm to 1550nm from being incident on the photodetector 34, and the photodetector 34 may receive only the light signal reflected by the diffuser 33 to output a detection electrical signal with higher accuracy, and the operating state of the light source 31 and/or the operating state of the diffuser 33 determined based on the detection electrical signal with higher accuracy may be more accurate.

Referring to fig. 2, 4, 7 and 8, the light receiving module 40 is disposed on the substrate 10, a light inlet 411 is formed on the light receiving module 40, and an external optical signal enters the light receiving module 40 after passing through the light inlet 411. In the embodiment of the present application, the plane forming the light passing port 541 may be flush with the plane forming the light entering port 411, so that the light signal passing through the light passing port 541 into the outside cannot be blocked by the light receiving module 40, and the light signal passing through the light entering port 411 from the outside cannot be blocked by the light emitting module 30.

The light receiving module 40 and the light emitting module 30 are disposed on the same substrate 10, so that the positions of the light receiving module 40 and the light emitting module 30 are relatively fixed, and the light receiving module 40 and the light emitting module 30 do not need to be fixed by using additional brackets. When the depth camera 100 is installed, the depth camera 100 may be integrally installed in the housing 200 without being calibrated after the light receiving module 40 and the light emitting module 30 are separately installed. In addition, the depth camera 100 may further include a connector 60, the connector 60 being connected to the substrate 10, the connector 60 being electrically connected to a main board of the electronic device 1000. The number of the connectors 60 may be single, and the single connector 60 may be electrically connected to the optical transmitter module 30 and the optical receiver module 40 simultaneously through the wiring, without providing a plurality of connectors 60. The light receiving module 40 includes a light sensing element 42, a filter 44, a lens barrel 41 and a lens assembly 43.

The photosensitive element 42 may be disposed on the substrate 10 and electrically connected to the substrate 10, the photosensitive element 42 being received in the second receiving cavity 52. The photosensitive element 42 is used for receiving only the optical signal which passes through the lens assembly 43 and has the waveband of 1350nm to 1550 nm. The material of photosensitive element 42 may include silicon and germanium, wherein the proportion of germanium is less than or equal to 10%, for example, the proportion of germanium may be 0.1%, 1%, 2.5%, 3.8%, 5%, 7%, 8%, 9%, 10%, etc. The material of the photosensitive element 42 may also include silicon and indium gallium arsenide. It is understood that the light sensing element made of silicon can only respond to the optical signal with the wavelength band of 350nm to 1064nm and cannot respond to the optical signal with the wavelength band of 1350nm to 1550nm, and the light sensing element 42 made of silicon and germanium or the light sensing element 42 made of silicon and indium gallium arsenic can respond to the optical signal with longer wavelength, such as the optical signal with the wavelength of 1350nm to 1550nm, so that the light sensing element 42 can be made of silicon and germanium or the light sensing element 42 can be made of silicon and indium gallium arsenic. After the light sensing element 42 receives the light signal, the light sensing element 42 converts the light signal into an electrical signal, which can be used for calculating depth information.

The optical filter 44 is disposed above the photosensitive element 42 and is accommodated in the second accommodating chamber 52. The optical filter 44 is used to transmit only the optical signals with the wavelengths of 1350nm to 1550nm, so that the photosensitive element 42 can receive only the optical signals with the wavelengths of 1350nm to 1550 nm. The lens assembly 43 may be mounted within the lens barrel 41. The lens assembly 43 may be comprised of a plurality (e.g., 4) of lenses. The light inlet 411 is opened in the lens barrel 41. After entering from the light inlet 411, the optical signal firstly passes through the lens assembly 43 and is incident on the optical filter 44, the optical filter 44 filters the optical signal with the wavelength beyond 1350nm to 1550nm, and finally, only the optical signal with the wavelength of 1350nm to 1550nm can be converged on the photosensitive element 42. The lens barrel 41 may be detachably mounted with the housing 50, and specifically, the lens barrel 41 may be detachably mounted with the second sub-housing 55. In the embodiment of the present application, the housing 50 further defines a mounting groove 53, and the mounting groove 53 can be used for mounting the lens barrel 41. The position of the mounting groove 53 may correspond to the position of the second receiving cavity 52. The outer wall of the lens barrel 41 is formed with an external thread, the inner wall of the mounting groove 53 is formed with an internal thread, and the lens barrel 41 and the housing 50 are detachably connected by the external thread and the internal thread, for example, the lens barrel 41 is screwed into the mounting groove 53, or the lens barrel 41 is screwed out of the mounting groove 53.

When the depth camera 100 is installed, the pad assembly 20 and the photosensitive element 42 may be first fixed on the substrate 10, and the conductive member 22 and the substrate 10, and the photosensitive element 42 and the substrate 10 may be electrically connected; then, the light emitting module 30 is mounted on the second surface 212 of the pad 21, and the light source 31 and the conductive member 22 are electrically connected; then, the housing 50 is fixed on the substrate 10, such that the light emitting module 30 and the pad module 20 are received in the first receiving cavity 51, and the photosensitive element 42 is received in the second receiving cavity 52; finally, the lens barrel 41 with the lens assembly 43 mounted thereon may be screwed into the mounting groove 53 to complete the assembly of the entire depth camera 100. Of course, the lens barrel 41 with the lens assembly 43 may be screwed into the mounting groove 53, and then the housing 50 with the lens barrel 41 mounted thereon may be fixed on the substrate 10. When necessary (for example, when the lens assembly 43 is replaced), the lens barrel 41 can be separated from the housing 50 without separating the housing 50 from the substrate 10.

Referring to fig. 1, 4 and 7, the processor 70 may be disposed outside the depth camera 100, for example, on a main board of the electronic device 1000, and electrically connected to the connector 60 of the depth camera 100. The processor 70 may also be disposed within the depth camera 100, such as within the light emitting module 30 or within the light receiving module 40. The processor 70 may calculate the depth information according to a time when the light emitting module 30 emits the light signal and a time when the light receiving module 40 receives the light signal. The processor 70 may also receive the detection electrical signal output by the light detector 34, and determine whether the light source 31 is in the constant power operating state and/or determine whether the diffuser 33 is in the normal operating state according to the detection electrical signal, and the specific determination process is as described above and will not be described herein again. The processor 70 may also control the light source 31 based on whether the light source 31 is in constant power operation and/or whether the diffuser 33 is in normal operation.

Specifically, when the detected electrical signal is equal to or within the first electrical signal range, the driving circuit for controlling the light source 31 to emit light by the processor 70 still drives the light source 31 to emit light at the current working current.

When the detected electrical signal is equal to or within the second electrical signal range, the processor 70 may control the driving circuit to increase the operating current to drive the light source 31 to emit light, so as to maintain the power output by the light source 31 at the target power. In one example, the increased operating current value may be selected by a temperature detector, and specifically, the light emitting module 30 may further include a temperature detector (not shown) disposed on the second surface 212 and adjacent to the light source 31, and the temperature detector is configured to detect the temperature of the light source 31. When the detected electrical signal is equal to or within the range of the second electrical signal, the processor 70 controls the temperature detector to detect the temperature of the light source 31, and the processor 70 finds out the target working current from the working current-power-temperature curve (different working current-power curves corresponding to different temperatures) according to the temperature, wherein the power corresponding to the target working current is at the target power at the current temperature of the light source 31. The processor 70 may control the driving circuit to drive the light source 31 to emit light at the target operating current, so that the light source 31 outputs a light signal with constant power. After the processor 70 controls the driving circuit to drive the light source 31 to emit light at the increased target operating current, the light detector 34 may further continue to receive the light reflected by the diffuser 33 and output a detection electrical signal, and at this time, if the detection electrical signal is equal to or within the range of the first electrical signal, the processor continues to control the driving circuit to drive the light source 31 to emit light at the increased target operating current; if the detected electrical signal is equal to the second electrical signal or within the second range, the processor 70 controls the temperature detector to detect the temperature of the light source 31 again, and updates the target operating current according to the temperature (the updated target operating current is higher than the target operating current before updating), and the processor 70 controls the updated target operating current to drive the light source 31 to emit light. The processor 70 gradually increases the working current for driving the light source 31 to emit light according to the feedback of the light detector 34, so as to ensure that the light source 31 can always output a light signal with constant Power through software design, thereby implementing an Automatic Power Control (APC) adjustment function of the light emitting module 30 (shown in fig. 15).

When the detection electrical signal is within the third electrical signal range, indicating that the diffuser 33 is not in a normal operation state, i.e., the diffuser 33 is damaged or falls off, the processor 70 may control the driving circuit to stop supplying the operating current to the light source 31 to turn off the light source 31. It will be appreciated that when the diffuser 33 is damaged or falls off, the diffuser 33 cannot diffuse the light signal emitted by the light source 31 into a uniform surface light, which may result in the depth camera 100 not being used properly. When the diffuser 33 is damaged or falls off, the processor 70 turns off the light source 31 to prevent the depth camera 100 from continuously emitting the light signal in the case of abnormal use, so that the power consumption of the electronic device 1000 can be saved.

In summary, in the light emitting module 30, the light receiving module 40, the depth camera 100 and the electronic device 1000 according to the embodiment of the present application, the light emitting module 30 emits the optical signal with the wavelength of 1350nm to 1550nm, the light receiving module 40 receives the optical signal with the wavelength of 1350nm to 1550nm, and there is almost no background optical signal with the wavelength of 1350nm to 1550nm in the ambient light, so as to avoid the influence of the background optical signal on the calculation of the time when the light receiving module 40 receives the optical signal, and further improve the accuracy of obtaining the depth information. In addition, the energy of the optical signal with longer wavelength is lower, and according to the characteristics of human eyes, the optical signal with longer wavelength can not be converged on the retina, so that the damage to the human eyes can be avoided by using the optical signal with the wavelength of 1350 nm-1550 nm.

In addition, the light emitting module 30 is further provided with a light detector 34 to detect the operating state of the light source 31 and the operating state of the diffuser 33, so that the light source 31 can be better controlled according to the operating state of the light source 31 and the operating state of the diffuser 33 detected by the light detector 34. When the diffuser 33 normally works but the light source 31 is not in the constant power working state, the working current of the light source 31 is increased, so that the light emitting module 30 can output an optical signal with stable power, and the acquisition precision of the depth information can be further improved. Turning off the light source 31 when the diffuser 33 is not operating properly may reduce power consumption of the electronic device 1000.

Furthermore, the light emitting module 30 is disposed on the second surface 212 of the spacer 21, and the light emitting module 30 is electrically connected to the substrate 10 through the conductive member 22, the spacer 21 increases the height of the light emitting module 30, the height difference between the light emitting module 30 and the light receiving module 40 is reduced, the light receiving module 40 is prevented from shielding the light emitting module 30 to emit light signals, the light signals emitted by the light emitting module 30 have a larger coverage area, the depth camera 100 can obtain depth information of more objects in a scene, and the obtained depth information is high in integrity.

Referring to fig. 5 and 12, in some embodiments, the light emitting module 30 may not include the reflective element 38. At this time, the light emitting surface 310 of the light source 31 directly faces the diffuser 33. The light source 31 may be a vertical cavity surface emitting laser or an edge emitting laser. When the light source 31 is an edge emitting laser, the number of edge emitting lasers may be one or more. The light signal emitted from the light source 31 passes through the light outlet 322 and reaches the diffuser 33, and the diffuser 33 can increase the viewing angle range of the light signal, so that the light signal emitted from the light emitting module 30 can be irradiated to a wider range. The optical signal passing through the diffuser 33 may further pass through the light-passing port 541, and after passing through the light-passing port 541, the optical signal is emitted out of the depth camera 100.

Referring to fig. 4, 5, 9 and 10, in some embodiments, the pad 21 further has a heat conduction hole 214, and the heat conduction hole 214 penetrates through the first surface 211 and the second surface 212. The pad assembly 20 further includes a heat conductive member 23, and the heat conductive member 23 is filled in the heat conductive hole 214. The light source 31 is disposed on the heat conductive member 23. The light source 31 generates heat during operation, and if the heat cannot be dissipated timely, the intensity, frequency, and other parameters of the light signal emitted by the light source 31 may be affected, so that the light source 31 cannot be maintained in a constant power operation state. At this time, if the light source 31 is disposed on the heat conducting member 23, the heat conducting member 23 can rapidly conduct the heat generated by the light source 31 to the substrate 10, and further conduct the heat to the outside through the substrate 10, so that the light source 31 can be maintained in a constant power operation state by hardware design.

Specifically, the heat conduction member 23 is filled in the heat conduction hole 214, and the heat conduction member 23 may be made of a material with better heat conduction performance, such as copper, silver, and the like. The heat conductive member 23 is exposed from the first surface 211 and the second surface 212 so that one end of the heat conductive member 23 contacts the light source 31 and the other end contacts the substrate 10. The orthographic projection of the light source 31 on the second surface 212 can completely fall onto the heat conducting member 23, so that the contact area between the light source 31 and the heat conducting member 23 is large, and the heat conducting efficiency is improved. In one example, the number of the heat conduction holes 214 is plural, a plurality of heat conduction holes are arranged at intervals, and the heat conduction member 23 arranged in each heat conduction hole 214 is in contact with the light source 31; in another example, the number of the heat conduction holes 214 is single, and the hollow volume of the single heat conduction hole 214 can be set to be larger than, for example, the sum of the hollow volumes of the plurality of heat conduction holes 214 when the plurality of heat conduction holes 214 are opened, so that a larger number of the heat conduction members 23 can be set in the single heat conduction hole 214 to improve the heat conduction efficiency.

Further, the heat conduction hole 214 may be formed in a shape with a smaller top and a larger bottom, that is, the size of the end of the heat conduction hole 214 close to the second surface 212 may be substantially the same as the area of the orthographic projection of the light source 31 on the second surface 212, and the size of the end close to the first surface 211 may be set larger than the area of the orthographic projection of the light source 31 on the second surface 212, so as to increase the contact area between the heat conduction member 23 and the substrate 10 and improve the heat conduction efficiency.

Referring to fig. 4 and 5, in some embodiments, when the photodetector 34 is disposed on the second side 212, the conductive via 213 may be used for the conductive member 22 to pass through to electrically connect the photodetector 34 and the substrate 10. The photodetector 34 and the conductive member 22 may be electrically connected by wire bonding, or the pins of the photodetector 34 may be in direct contact with the conductive member 22. In addition, the position aligned with the photodetector 34 may be provided with the above-mentioned heat conduction hole 214, and the heat conduction member 23 in the heat conduction hole 214 may be used to quickly conduct the heat generated by the operation of the photodetector 34 to the substrate 10, so as to ensure the normal operation of the photodetector 34.

In some embodiments, the light emitting module 30 may not have the filter 37. In this case, the photodetector 37 may be provided as an element capable of receiving only optical signals of 1350nm to 1550 nm. Specifically, the wavelength band of operation of the optical detector 34 may be varied by changing the material composition in the optical detector 34 such that the optical detector 34 operates only in the wavelength band of 1350nm to 1550 nm.

In some embodiments, the light receiving module 40 may not be provided with the optical filter 44, and in this case, the photosensitive element 42 may be a photosensitive element that only receives the optical signals of 1350nm to 1550 nm. Specifically, the operating band of the photosensitive element 42 may also be changed by changing the material composition in the photosensitive element 42 so that the photosensitive element 42 operates only in the band of 1350nm to 1550 nm.

In some embodiments, the light emitting module 30 and the light receiving module 40 may also be disposed on two independent substrates 10 and connected to the main board of the electronic device 1000 through two connectors 60.

In the description herein, reference to the description of the terms "certain embodiments," "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples" means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of the feature. In the description of the present application, "a plurality" means at least two, e.g., two, three, unless specifically limited otherwise.

Although embodiments of the present application have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present application, and that variations, modifications, substitutions and alterations of the above embodiments may be made by those of ordinary skill in the art within the scope of the present application, which is defined by the claims and their equivalents.

Claims (12)

1. The utility model provides a light emission module, its characterized in that, light emission module includes:

the optical source is used for transmitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm;

a reflecting surface of the reflecting element is opposite to a light emitting surface of the light source, and the reflecting element is used for reflecting the optical signal; and

a diffuser for diffusing the optical signal after being reflected by the reflective element.

2. The utility model provides a light emission module, its characterized in that, light emission module includes:

the optical source is used for transmitting optical signals, and the wavelength of the optical signals is 1350 nm-1550 nm; and

a diffuser with a light emitting face of the light source facing the diffuser, the diffuser for diffusing the optical signal.

3. The optical transmission module according to claim 1 or 2, wherein when the light source is an edge-emitting laser, the edge-emitting laser is plural, and the plural edge-emitting lasers are connected in parallel.

4. The light emitting module of claim 3, wherein the light source is connected to the substrate via a plurality of conductive wires.

5. The optical transmit module according to claim 1 or 2, further comprising a photodetector for receiving the optical signal reflected back by the diffuser to form a detection electrical signal, wherein the detection electrical signal is used as a basis for determining whether the optical source is in a constant power operation state and/or as a basis for determining whether the diffuser is in a normal operation state.

6. The optical transmitter module as claimed in claim 5, wherein the diffuser includes an incident surface and an emergent surface opposite to each other, the incident surface is opposite to the light source, and the emergent surface is provided with a high-reflectivity film for reflecting optical signals with wavelengths of 1350nm to 1550 nm.

7. The optical transmit module of claim 6, wherein the diffuser comprises a coated area and an uncoated area connected to the coated area, the high reflective film is formed on the coated area, the uncoated area corresponds to the optical signal area emitted by the light source, and the coated area corresponds to the light receiving area of the light detector.

8. The optical transmitter module as claimed in claim 6, wherein the optical detector has an operating wavelength of 1350nm to 1550 nm.

9. The optical transmit module of claim 6, wherein the optical detector is disposed with a filter for transmitting optical signals with wavelengths of 1350nm to 1550 nm.

10. A depth camera, characterized in that the depth camera comprises:

the light emission module of any of claims 1-9; and

and the optical receiving module is used for receiving the optical signal which is emitted by the optical emitting module and reflected.

11. The depth camera of claim 10, wherein the light emitting module comprises a light detector for receiving light signals reflected back by the diffuser to form a detected electrical signal, the depth camera further comprising a processor for:

determining whether the light source is in a constant power working state and/or determining whether the diffuser is in a normal working state according to the detection electric signal; and

and controlling the light source according to whether the light source is in a constant-power working state and/or whether the diffuser is in a normal working state.

12. An electronic device, characterized in that the electronic device comprises:

a housing; and

the depth camera of claim 11, in combination with the housing.

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