FR3057434A1 - CAMERA DEVICE HAVING AN ALIGNMENT SYSTEM WITH AN IMAGE SENSOR - Google Patents

Abstract

A camera device (10) for a motor vehicle comprises a printed circuit board (16), an image sensor (12) mounted on the printed circuit board (16), the image sensor (12) comprising an axis main sensor (AC), a lens (14) mounted on a support (24) which is fixed on the printed circuit board (16), the lens (14) being arranged opposite the image sensor (12), its main optical axis (OP) being provided to be aligned with the main sensor axis (AC), the lens (14) is mounted on the support (24) via at least three pillars ( 18, 20, 22), each pillar (18, 20, 22) having a variable height controlled electrically in the direction of the main sensor axis (AC), so as to allow alignment of the optical axis (OP ) of the lens (14) with the main sensor axis (AC).

Description

TECHNICAL AREA

The present invention relates to a camera device and more particularly to means for aligning the camera lens with the image sensor of said camera.

TECHNOLOGICAL BACKGROUND OF THE INVENTION

Camera devices providing security functions for motor vehicles are subjected to a hostile environment, such as strong temperature gradients, which can influence the mechanical and electrical parameters of such devices. The distance between a camera lens and its image sensor is fundamental for optimal performance of camera vision systems. It is known today to be able to adjust and readjust this previously optimized distance when a difference occurs. Current solutions only allow the distance between the lens and the image sensor to be adjusted along a single axis. However, it has become apparent that these devices are not sufficient to correct all of the misalignments between the lens and the image sensor of a camera device, in particular a tilting misalignment of the lens with the image sensor, or even a horizontal offset between the lens and the image sensor.

It is therefore important to offer a new solution to these problems.

SUMMARY OF THE INVENTION

A camera device for a motor vehicle comprises a printed circuit board, an image sensor mounted on the printed circuit board, the image sensor comprising a main sensor axis, a lens mounted on a support which is fixed on the printed circuit board, the lens being arranged opposite the image sensor, its main optical axis being provided to be aligned with the main sensor axis. The lens is mounted on the support by means of at least three pillars, each pillar having a variable height electrically controlled in the direction of the main sensor axis so as to allow the alignment of the optical charge of the lens with Main sensor fee. This arrangement also makes it possible to control the distance between the image sensor and the lens.

Each pillar can be fixed to each of its ends by a flexible and elastic adhesive. The pillars can include piezoelectric elements. The pillars can be three in number and can be spaced each other by an angle of about 120 degrees around the main sensor fee. The printed circuit board may include an electrical control circuit which allows the height of the pillars to be varied. The control circuit can be configured to independently adjust the height of each pillar. The lens can be arranged in a frame and the pillars can be interposed directly between the support and the frame.

If necessary, especially if the device needs to be protected against a hostile environment, a seal can be compressed between a cylindrical wall of the chassis and a cylindrical wall of the support. A seal can be compressed into a cylindrical groove hollowed out on the surface of the upper end of the support by the free end of a cylindrical wall of the chassis.

The chassis may include two concentric vertical walls, the free ends of the two vertical walls being supported in two concentric grooves arranged on the surface of the upper end of the support.

The camera device can also comprise at least 3 actuators adjustable in length in directions transverse to the main sensor charge, said actuators being interposed between the frame and the lens so as to allow the alignment of the main optical charge of the lens with charge. main sensor. The actuators can be three in number and can be spaced each other by an angle of about 120 degrees around the main sensor.

BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics, objects and advantages of the invention will appear on reading the detailed description which follows, and with reference to the appended drawings, given by way of non-limiting example and in which:

Figure 1 is a perspective view in section along a vertical axis which represents a camera device according to a first embodiment.

Figure 2 is a top view without the optical lens of the device of Figure 1.

FIG. 3 is a side view in transparency of the device of FIG. 1.

Figure 4 is a schematic view in axial section of the holding region of the optical lens of the camera device according to a second embodiment.

Figure 5 is a schematic view in axial section of the holding area of the optical lens of the camera device according to a third embodiment.

Figure 6 is a perspective view in axial section of the holding area of the optical lens of the camera device, without the lens, according to a fourth embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

According to FIG. 1, a camera device 10 for a motor vehicle comprises an image sensor 12 and an optical lens 14. The image sensor 12 is disposed on a printed circuit board 16. The lens 14 rests directly on pillars 18, 20. Said pillars 18, 20 rest on a support 24 of hollow cylindrical type fixed on the printed circuit board 16. The support 24 extends along a vertical axis V, the said vertical axis V also being the axis of revolution of the cylinder. The support 24 is a circular base cylinder, the circular base of which surrounds the image sensor 12. The support 24 is a few millimeters thick. The pillars 18, 20 are therefore interposed between the lens 14 and the upper end 26 of the support 24. Preferably the lens 14 is fixed to the pillars 18, 20 by means of an adhesive of the elastic type.

The lens 14, of generally circular shape, comprises a main optical axis OP oriented along a vertical axis V perpendicular to the surface 17 of the printed circuit board 16. The main optical axis OP is the axis passing through the barycenter of the lens 14; a light ray passing through the lens 14 through the barycenter is not deflected.

The image sensor 12 includes a main axis of the AC sensor. The main axis of the image sensor AC is defined as the vertical axis to the sensor AC passing through the barycenter of the sensor 12. The lens 14 and the image sensor 12 are arranged so that the main optical axis OP of the lens is ideally aligned with the main axis of the AC image sensor.

According to Figure 2, the camera device 10 is shown in top view, without the lens 14. The pillars 18, 20, 22 are three in number. The three pillars 18, 20, 22 are fixed on the surface 27 of the upper end 26 of the support 24. Preferably, the three pillars 18, 20, 22 are fixed with a flexible adhesive on the surface 27 of the upper end 26 of the support 24. The pillars 18, 20, 22 are separated from each other in an equidistant manner. In particular, the three pillars 18, 20, 22 are separated by an angular distance of about 120 degrees.

According to FIG. 3, the three pillars 18, 20, 22 are substantially of the same height H _i8 , H ₂ o, H ₂ 2. The height H _i8 , H ₂₀ , H ₂₂ of each pillar 18, 20, 22 is adjusted so as to align the main optical axis OP of the lens 14 with the main axis AC of the image sensor 12. The particularity of the invention lies in the fact that the three pillars 18, 20, 22 are electrically adjustable in height in the vertical direction, preferably of the order of a few micrometers, so as to precisely align the main optical axis OP of the lens 14 with the main axis AC of the image sensor 12. Preferably, the three pillars 18, 20, 22 are piezoelectric elements capable of retracting or extending by a few micrometers by means of a voltage control. Preferably, the pillars 18, 20, 22 are of cylindrical shape or also can be in the form of prisms or truncated prisms. The camera device 10 comprises a voltage control circuit 28 making it possible to independently apply to each pillar 18, 20, 22 a voltage for adjusting its height H _i8 , H ₂₀ , H ₂₂ . The control circuit 28 is therefore electrically connected to the pillars 18, 20, 22. Although shown on the printed circuit board 16, the control circuit 28 can be arranged elsewhere in the vehicle, in particular in an electronic computer electrically connected to the device camera 10.

The invention makes it possible not only to adjust the distance D between the image sensor 12 and the lens 14, so as to adjust the sharpness of the image, but also to adjust the inclination of the lens 14 with the sensor image 12 so as not to have image distortion if it turns out that the main optical axis OP of the lens 14 was not aligned with the main axis AC of the image sensor

12. This invention makes it possible to be able to adjust the sharpness of the captured images and to remove image distortions dynamically, more particularly in conditions of vehicle travel. Indeed, the automotive environment, in particular the climatic conditions, and other mechanical stress factors can cause a misalignment of the main optical axis OP of the lens 14 with the main axis AC of the image sensor 12 by deformation of the printed circuit board 16 and / or of the support 24. The equidistant arrangement of approximately 120 degrees between each pillar 18, 20, 22 makes it possible to correct any vertical misalignment between the main optical axis OP of the lens 14 and the main axis AC of the image sensor 12.

According to Figure 4, a second embodiment is shown. The pillar 18 shown is identical to the pillars 18, 20, 22 described through FIGS. 1, 2 and 3. Although only one pillar 18 is shown, the other two pillars 20, 22 are arranged identically to that shown in FIG. 4. Unlike the first embodiment shown through FIGS. 1, 2 and 3, the lens 14 rests on a frame 30 bearing on the pillar 18.

According to this embodiment, the upper end 26 of the support 24 has an axial section profile in the form of a fork with three straight teeth 32, 34, 36, a central tooth 34, a tooth external 32 to the device, and an internal tooth. 36 to the device 10. The three teeth 32, 34, 36 are spaced apart by two inter-tooth spaces 38, 40, an external inter-tooth space 38 to the device 10 and an internal inter-tooth space 40 to the device 10. The abutment 18 is arranged on the central tooth 34.

The chassis 30 has a generally hollow cylindrical shape having a shape complementary to the upper end 26 of the support 24. The axis of revolution of the chassis 30 is coincident with the axis of revolution of the support 24. The chassis 30 therefore comprises an opening central circular 15 covered by the lens 14. More precisely, the chassis 30 has a profile in axial section of an inverted 'U' therefore comprising a base 42 and two parallel walls 48, 50. The chassis is therefore inserted in a complementary manner with the upper end 26 of the support 24, so as to rest on the pillars 18, 20, 22.

More particularly, the horizontal circular base 42 of the frame 30 is in abutment on the pillar 18 and the two vertical walls 48, 50 cylindrical and concentric extend parallel on either side of the base 42 towards the inter-tooth spaces 38 , 40. The horizontal base 42 has an internal surface 46 oriented towards the pillar 18 and an external surface 44 opposite the internal surface 46. In other words, the internal surface 46 of the base 42 of the 'U' comes to bear on the pillar 18. Preferably the inner surface 46 of the base 42 of the 'U' is fixed with an elastic adhesive on the pillar 18 so as to resist the elongation or retraction of the pillar 18. The free ends 52, 54 of the two walls 48, 50 are inserted into the two inter-tooth spaces 38, 40. Preferably, each free end 52, 54 of the two walls 48, 50 compresses an annular seal 56, 58 arranged on each bottom 60, 62 of each inter-tooth space 38, 40. The structure obtained makes it possible to protect the image sensor by a double wall which is waterproof and dustproof.

It is entirely possible to design a device 10 without a seal 56, 58. The free ends 52, 54 of the vertical walls 48, 50 can be arranged in abutment against the support 24 and more particularly against the bottom 60, 62 inter-tooth spaces 38, 40. In other words, the free ends 52, 54 of the two concentric vertical walls 48, 50 of the frame 30 come to bear in two concentric grooves arranged on the surface 27 of the upper end 26 of the support 24. This embodiment guarantees a certain level of protection against dust and the introduction of liquid.

Alternatively, the chassis 30 may have only one vertical wall 48. The upper end 26 of the support 24 may have an axial section profile in the form of a fork with two straight teeth 32, 36, an external tooth 32 at device, and an inner tooth 36 to the device 10. The two teeth 32, 36 are spaced apart by a central inter-tooth space 38. The pillar 18 is arranged on the inner tooth 36. The free end 52 of said vertical wall 48 compresses a seal 56 arranged in the bottom of the inter-tooth space 38. In other words, more generally, the seal is obtained by compression of the seal 56 arranged in a cylindrical groove hollowed out on the surface 27 of the upper end 26 of the support 24 by the free end 52 of a cylindrical wall 48 of the chassis 30.

Also, in the case of a lens support comprising two vertical walls 48, 50, a single inter-tooth space 38 can be provided at its bottom 60 with a seal 56 compressed by the free end 52, 54 d 'one of the two walls 48, 50.

The outer perimeter 64 of the lens 14 is fixed on the outer surface 44 of the base 42 of the "U". The outer surface 44 of the base 42 of the ‘U’ is complementary to the shape of the outer perimeter 64 of the lens 14. As shown, the outer perimeter 64 of the lens 14 has a curved shape. Preferably, the lens 14 is fixed to the outer surface 44 of the base 42 of the ‘U’ by a flexible adhesive.

According to Figure 5, a third embodiment is shown. The pillar 18 shown is identical to the pillars 18, 20, 22 described through FIGS. 1, 2 and 3. Although only one pillar 18 is shown, the other two pillars 20, 22 are arranged identically to that shown in Figure 5. In this embodiment, the lens 14 rests on a frame 66 different from that of the second embodiment. This frame 66 is supported on the pillar 18. The support 24 is identical to that of the first embodiment shown through FIGS. 1, 2 and 3. The pillar 18 is therefore interposed between the surface 27 of the upper end 26 of the support 24 and the chassis 66.

The chassis 66 has a generally hollow cylindrical shape. The axis of revolution of the chassis 66 is coincident with Tax of revolution of the support 24. The chassis 66 therefore comprises a central circular opening 67 covered by the lens 14. More precisely, the chassis 66 has a horizontal circular base 68 resting on the pillar 18.

The circular base 68 has a horizontal internal surface 70 oriented towards the pillar 18 and in contact with the pillar 18 and an upper surface 72, opposite the internal surface 70, complementary to the shape of the external perimeter 64 of the lens 14. Such as shown, the lens 14 of this embodiment is identical to that of the second embodiment. The chassis 66 also includes a vertical wall 74 extending vertically from the outer end of the circular base 68, along the pillar 18, until it is opposite the support 24 so as to form a cylindrical side wall 74 vertical protection against water or dust intrusion on the image sensor. In order to guarantee this seal, this vertical wall 74 compresses against a wall 77 of the support 24 a circular seal 76, arranged around the support 24. Preferably, this seal is made of rubber.

According to Figure 6, a fourth embodiment is shown. The camera device 10 comprises pillars 18, 20 identical to the pillars 18, 20, 22 described through FIGS. 1, 2 and 3 allowing an electrical adjustment along the vertical axis V of the height of the lens 14 vis-à-vis screw of the image sensor 12 or of the inclination of the lens 14.

The particularity of this embodiment lies in the fact that it also comprises actuators 78, 80 electrically adjustable in length in directions D1, D2 transverse to the vertical axis V, allowing electrical adjustment of the horizontal position of lens 14 vis-à-vis the image sensor 12. Preferably, the actuators are piezoelectric elements voltage-controlled by the control circuit 28 (shown in FIG. 3).

Although FIG. 6 represents only two pillars 18, 20 and two actuators 78, 80, the device 10 preferably comprises three pillars 18, 20, 22 and three actuators 78, 80.

Similarly to the second embodiment shown in Figure 4, the pillars 18, 20 are fixed on the surface 27 of the upper end 26 of the support 24. More particularly, the pillars 18, 20 are arranged on the central tooth 34 of the support 24 having a fork-shaped axial section profile with three straight teeth 32, 34, 36. Preferably, the pillars 18, 20 are fixed with a flexible adhesive to the central tooth 34 of the support 24.

The device 10 represented comprises a chassis 82 comprising a first chassis element 84 and a second chassis element 86.

The first element 84 has similarities to the chassis 30 of the second embodiment shown in FIG. 4. The first element 84 has a generally hollow cylindrical shape. The axis of revolution of the first element 84 coincides with the axis of revolution of the support 24.

The first element 84 has a generally annular and horizontal base 88 bearing on the pillars 18, 20 and a cylindrical wall 90 extending vertically from the base 88 towards the inter-tooth space outside 38 of the device 10.

The base 88 is fixed to the pillars 18, 20 with an elastic adhesive so as to resist elongation or retraction of the pillars 18, 20 electrically adjustable in height in the vertical direction. The base 88 has a central circular opening 92 in which the lens 14 is arranged. The circular opening 92 is delimited by the inner periphery 94 of the base 88. The base 88 has an internal flat surface 96 oriented towards the first pillars 18, 20 and a flat outer surface 98 opposite the inner surface 96. In other words, the inner surface 96 of the base 88 bears on the pillars 18, 20. Preferably the inner surface 96 of the base 88 is fixed with an elastic adhesive on the pillars 18, 20 so as to resist the elongation or retraction of the pillars 18, 20. The inner surface 96 of the base 88 and the outer surface 98 of the base 88 are spaced apart by a thickness E.

The base 88 of the first element 84 comprises a circular groove 100 arranged at the inner periphery 94 of the base 88 and opening towards the circular opening 92 of the base 88. The groove 100 is hollowed out between the interior surface 96 of the base 88 and the external surface 98 of the base 88. The circular groove 100 therefore comprises a ceiling 114 opposite the flat external surface 98 of the base 88 and a bottom 112 opposite the internal surface 96 of the base 88. The groove 100 also comprises a circular side wall 110 extending vertically from the ceiling 114 to the bottom 112 of the groove 100.

The free end 116 of the vertical wall 90 is inserted into the outer inter-tooth space 38. Preferably, the free end 116 of the vertical wall 90 compresses an annular seal (not shown) arranged on the bottom of the outer inter-tooth space 38. The structure obtained makes it possible to protect the image sensor 12 by a wall 90 sealed against water and dust.

The second element 86 is a disc-shaped annular element, having a central circular opening 118. The periphery of the lens (not shown) is arranged on the second element 86 so as to be aligned with the image sensor (not shown) ). The second element 86 includes an outer edge 120 bordering its outer periphery 122. The outer periphery ίο

122 of the second element 86 is arranged in the circular opening 92 of the first element 84. More particularly, the outer periphery 122 of the second element 86 is inserted in the circular groove 100 of the base 88 of the first element 84. The second element 86 comes therefore resting on the bottom 112 of the groove 100.

The particularity of this embodiment resides in the fact that the actuators 78, 80 are interposed horizontally between the side wall 110 of the circular groove 100 and the outer edge 120 of the second element 86. The actuators 78, 80 are fixed in a horizontal position on the one hand on the side wall 110 of the circular groove 100, and on the other hand on the outer edge 120 of the second element 86. Preferably the actuators 78, 80 are fixed by an elastic adhesive so as to resist elongation or at the retractions in the directions Dl, D2 transverse to the vertical axis V.

In particular, the device comprises three actuators 78, 80 separated by an angular distance of approximately 120 °.

In this fourth embodiment, in addition to being able to adjust the distance between the image sensor 12 and the lens 14, so as to adjust the sharpness of the image, and also to adjust the inclination of the lens, it it is possible, thanks to the actuators 78, 80 to adjust the horizontal alignment of the lens 14 with the image sensor 12 so as to obtain the best possible resolution of the image, that is to say so as to be able to capture the image through the lens 14 with a maximum of pixels from the image sensor 12.

In all the embodiments described, the support 24 and the frames 30, 66, 82 can be made of plastic.

Claims (10)

CLAIMS: 1. Camera device (10) for a motor vehicle comprising a printed circuit board (16), an image sensor (12) mounted on the printed circuit board (16), the image sensor (12) comprising a main sensor axis (AC), a lens (14) mounted on a support (24) which is fixed on the printed circuit board (16), the lens (14) being arranged opposite the sensor image (12), its main optical axis (OP) being designed to be aligned with the main sensor charge (AC), characterized in that the lens (14) is mounted on the support (24) by means of at minus three pillars (18, 20, 22), each pillar (18, 20, 22) having a variable height electrically controlled in the direction of Main sensor charge (AC), so as to allow alignment of Optical charge (OP ) of the lens (14) with Main sensor charge (AC). 2. Device (10) according to the preceding claim, characterized in that the pillars (18, 20, 22) comprise piezoelectric elements. 3. Device (10) according to any one of the preceding claims, characterized in that the pillars (18, 20, 22) are three in number and they are spaced apart from each other by an angle of approximately 120 degrees around Main sensor tax (AC). 4. Device (10) according to any one of the preceding claims, characterized in that the printed circuit board (16) comprises an electrical control circuit (18) which makes it possible to modify the height of the pillars (18, 20, 22). 5. Device (10) according to claim 4, characterized in that the control circuit (18) is configured to independently adjust the height of each pillar (18, 20, 22). 6. Device (10) according to any one of the preceding claims, characterized in that the lens (14) is arranged in a frame (30, 66, 82) and in that the pillars (18, 20, 22) are interposed directly between the support (24) and the chassis (30, 66, 82). 7. Device (10) according to the preceding claim, characterized in that a seal (76) is compressed between a cylindrical wall (48, 74, 90) of the chassis (30, 66, 82) and a cylindrical wall (77) of the support (24). 8. Device (10) according to claim 6 characterized in that a seal (56) is compressed in a cylindrical groove hollowed out on the surface (27) of the upper end (26) of the support (24) by the free end (52) of a cylindrical wall (48) of the chassis (30). 9. Device (10) according to any one of claims 6 to 8, characterized in that it comprises at least 3 actuators (78, 80) adjustable in length along directions (Dl, D2) transverse to the axis of main sensor (AC), said actuators (78, 80) being interposed between the frame (82) and the lens (14) so as to allow the alignment of the main optical axis of the lens (OP) with the axis sensor main (AC). 10. Device (10) according to any one of claims 6 to 9 characterized in that, the actuators (78, 80) are three in number and they are each spaced from each other by an angle d '' about 120 degrees around the main sensor axis (AC). 1/4