FR3118209A1 - Method for adjusting an optical device and diffraction plate - Google Patents

Abstract

The invention relates to a method for adjusting an optical device comprising the following steps:- mounting (100) a diffraction plate on a mount; - emission (102) of a light beam; - acquisition (104) of an image by a set of sensors, said image comprising a first, a second, a third and a fourth straight line of diffraction; - displacement (106) of the sensor array along the optical axis until the second, third, and fourth straight lines intersect at a point;- rotation (108) of the sensor array about the axis optical;- rotation (112) of the sensor assembly about a vertical axis. The invention also relates to a method for harmonizing a diffraction plate and an optical system. Figure to be published with abstract: Figure 3

Description

Method for adjusting an optical device and diffraction plate

Technical field of the invention

The present disclosure relates to the field of optronic systems such as viewfinders equipped with cameras and methods for adjusting these cameras on their mounting interface.

State of the prior art

Diffraction plates are known to facilitate the development of astronomical instruments for astrophotography. These diffraction plates make it possible to adjust the focusing of the system but do not make it possible to make an orientation adjustment (rotation around the average axis of propagation of the rays or perpendicularity of the image plane with respect to this axis).

Presentation of the invention

The object of the present invention is to propose a method for the rapid adjustment of the focus, the slope, the vertical inclination and the horizontal inclination of a set of sensors, as well as an optical system and a diffraction plate. allowing the implementation of the process. The object of the present invention is also to propose the rapid adjustment of the harmonization, that is to say the alignment of the reference axis of the camera with respect to the reference axis of the receiver device of the camera. .

To this end, the subject of the invention is a method for adjusting an optical device using a diffraction plate; said diffraction plate comprising at least two centering elements, a first zone, a second zone, a third zone and a fourth zone, each zone having diffraction slots extending in different directions; said optical device having an optical reference axis and comprising:
- a light source capable of emitting a light beam having a plane wave front;
- a mounting device extending parallel to the optical reference axis, said mounting device comprising a mount having at least two complementary centering elements, a lens, a set of sensors capable of acquiring a diffraction image, and a adjustable support able to carry said set of sensors; said orientable support being adapted to move along the optical axis, said orientable support being adapted to pivot around the optical axis, a vertical axis of inclination and a horizontal axis of inclination; the optical reference axis, the vertical axis of inclination and the horizontal axis of inclination forming a rectangular trihedron; the said set of sensors comprising pixels aligned along rows and columns; said method comprising the following steps:
- mounting of the diffraction plate on the frame and mechanical cooperation of the centering elements of the diffraction plate with the complementary centering elements of the frame;
- Emission by the light source of a light beam propagating along the optical reference axis;
- acquisition of an image by the set of sensors, said image being a diffraction image comprising a first, a second, a third and a fourth straight diffraction line;
- displacement of the set of sensors along the optical reference axis until the second straight line, the third straight line and the fourth straight line intersect at a point of intersection to adjust the focus;
- rotation of the set of sensors around the optical reference axis until the first straight line of diffraction is aligned with a column of pixels of the set of sensors to adjust a cant,
- rotation of the set of sensors around the horizontal axis of inclination until the second straight line of diffraction is perpendicular to the first straight line of diffraction, to adjust the horizontal inclination of the set of sensors ,
- rotation of the set of sensors around the vertical axis of inclination until the third straight line of diffraction is perpendicular to the orientation direction of the diffraction slits of the third zone, and until that the fourth straight diffraction line is perpendicular to the orientation direction of the diffraction slits of the fourth zone, to adjust the vertical inclination of the set of sensors.

Thus, the presence of an invariant on the diffraction plate, in association with knowledge of the positioning of the diffraction plate, makes it possible to find one's way for adjusting the cant and the inclination of the set of sensors.
Furthermore, thanks to this fine adjustment of the position of the set of sensors, when other sets of sensors are used in parallel in order to provide a better image, it is easier to harmonize the adjustments between the positions of the different sets of sensors.

According to one embodiment, the steps of adjustment of focus, cant, adjustment of vertical inclination of the set of sensors and adjustment of horizontal inclination of the set of sensors are carried out at least once in this sequential order.

The invention also relates to a method for harmonizing at least a first optical device and a second optical device using a diffraction plate, the first and the second optical device each comprising a mount, a lens and a set of sensors aligned on an optical axis, the harmonization method comprising the following steps:
- implementation of the steps of the adjustment method mentioned above on the first optical device;
- implementation of the steps of the adjustment method mentioned above on the second optical device using the diffraction plate used to adjust the first optical device.

The invention also relates to a diffraction plate for focusing an optical device comprising a lens having an optical reference axis, the diffraction plate comprising:
- a first zone having diffraction slots extending along a first direction, the first zone being intended to be aligned with the optical reference axis of the lens;
- a second zone having diffraction slots extending in a second direction,
- a third zone having diffraction slots extending along a third direction, the third direction having an angle defined with respect to the first direction;
- a fourth zone having diffraction slots extending along a fourth direction, the first direction, the second direction, the third direction and the fourth direction having different orientations.
According to one embodiment, the first, the second, the third and the fourth zones have substantially a surface of the same area.

According to one embodiment, the plate further comprises at least two centering elements making it possible to position the diffraction plate in a predefined position on a mount.

According to one embodiment, the first direction is horizontal.

According to one embodiment, the second zone, the third zone and the fourth zone have the shape of an angular portion of a ring; said ring having as its center the center of the first zone, and in which the second, the third and the fourth zones surround the first zone.

According to one embodiment, said predefined angle is between 50° and 70° and is preferably equal to 60° .

Thus, the plate according to the invention makes it possible to effectively and quickly adjust all the degrees of freedom of the relative position of the set of sensors of the optical device with respect to the objective of the optical device.

Thanks to these characteristics, in use, when it is placed in the vicinity of the entrance pupil of an optical device such, for example, a camera, for example an optronic instrument, the diffraction plate acts as a diffraction mask on the optical path of the optical device, in order to facilitate the focusing of the optical device.

Finally, the subject of the invention is an optical system comprising an optical device having an optical reference axis and a diffraction plate, characterized in that the diffraction plate is shaped according to the characteristics mentioned above, and in that that the optical device comprises:
- a light source capable of emitting a light beam having a plane wave front and propagating along the optical reference axis;
- a mounting device extending parallel to the optical axis, said mounting device comprising a mount having at least two complementary centering elements, a lens arranged on the optical axis, a set of sensors able to acquire an image of diffraction, and an orientable support able to carry said set of sensors; said orientable support being adapted to move along the optical axis and to pivot around the optical axis, a vertical axis of inclination and a horizontal axis of inclination; the optical axis, the vertical axis of inclination and the horizontal axis of inclination forming a rectangular trihedron; the said set of sensors comprising pixels aligned along rows and columns.

Brief description of figures

is a diagram of an optical system according to the invention;

is a diagram of a diffraction plate according to one embodiment of the invention;

is a diagram representing the steps of the method for adjusting the optical device according to the invention;

is a diffraction image obtained by the diffraction plate of the ;

is an image obtained after processing the image of the .

Claims (10)

Method for adjusting an optical device (8) using a diffraction plate (1); said diffraction plate comprising at least two centering elements (26), a first zone (3), a second zone (4), a third zone (5) and a fourth zone, each zone having diffraction slots extending in different directions; said optical device (8) having an optical reference axis (13) and comprising:
- a light source (32) capable of emitting a light beam having a plane wavefront;
- a mounting device (30) extending parallel to the optical reference axis, said mounting device (30) comprising a mount (12) having at least two complementary centering elements (34), a lens (9) , a set of sensors (10) capable of acquiring a diffraction image, and an orientable support (36) able to carry said set of sensors; said orientable support being adapted to move along the optical axis, said orientable support being adapted to pivot around the optical axis (13), a vertical axis of inclination (Z) and an axis ( Y) tilt horizontal; the optical reference axis (13), the vertical tilt axis (Z) and the horizontal tilt axis (Y) forming a rectangular trihedron; said set of sensors comprising pixels aligned along rows and columns ; said method comprising the following steps:
- Mounting (100) of the diffraction plate (1) on the mount (12) and bringing the centering elements (26) of the diffraction plate into mechanical cooperation with the complementary centering elements (34) of the mount;
- emission (102) by the light source (32) of a light beam propagating along the optical reference axis;
- acquisition (104) of an image by the set of sensors (10), said image being a diffraction image comprising a first (19), a second (20), a third (21) and a fourth (22) straight lines of diffraction;
- displacement (106) of the set of sensors along the optical reference axis until the second straight line (20), the third straight line (21) and the fourth straight line (22) intersect at a point of intersection (I) to adjust the focus;
- rotation (108) of the sensor assembly (10) around the optical reference axis until the first (19) straight line of diffraction is aligned with a column of pixels of the sensor assembly to adjust a slope,
- rotation (110) of the set of sensors (10) around the horizontal axis of inclination (Y) until the second (20) straight line of diffraction is perpendicular to the first (19) straight line diffraction, to adjust the horizontal inclination of the set of sensors,
- rotation (112) of the set of sensors (10) around the vertical axis of inclination (Z) until the third (21) straight line of diffraction is perpendicular to the orientation direction of the slits diffraction slit of the third zone (5), and until the fourth straight diffraction line (22) is perpendicular to the orientation direction of the diffraction slits of the fourth zone (6), to adjust the inclination vertical of the sensor assembly. A method of adjustment according to claim 1, wherein the steps of adjusting focus, cant, adjusting vertical tilt of the sensor assembly and adjusting horizontal tilt of the sensor assembly are performed at least once in this sequential order. Method for harmonizing at least a first optical device (8) and a second optical device using a diffraction plate (1), the first and the second optical device each comprising a mount (12) , a lens (9) and a set of sensors (10) aligned on an optical axis (13), the harmonization method comprising the following steps:
- implementation of the steps (100 to 112) of the adjustment method mentioned in any one of claims 1 and 2 on the first optical device (8);
- implementation of the steps (100 to 112) of the adjustment method mentioned in any one of claims 1 and 2 on the second optical device using the diffraction plate (1) used to adjust the first optical device ( 8). Diffraction plate (1) for focusing an optical device (8) comprising an objective (9) having an optical reference axis (13), a light source (32), a mounting device (30) comprising a mount (12) having at least two complementary centering elements (34), a set of sensors (10) and an orientable support (36) adapted to pivot around the optical axis (13), the reference axis optic (13), a vertical axis of inclination (Z) and a horizontal axis (Y) of inclination forming a rectangular trihedron; the said set of sensors comprising pixels aligned along lines and columns the diffraction plate (1) comprising:
- at least two centering elements (26),
- a first zone (3) having diffraction slots extending along a first direction (D1), the first zone (3) being intended to be aligned with the optical reference axis (13) of the lens;
- a second zone (4) having diffraction slots extending in a second direction (D2),
- a third zone (5) having diffraction slots extending along a third direction (D3), the third direction having a defined angle (α) with respect to the first direction;
- a fourth zone (6) having diffraction slits extending along a fourth direction (D4), the first direction (D1), the second direction (D2), the third direction (D3) and the fourth direction (D4) with different orientations. Diffraction plate (1) according to claim 4, in which the first, the second, the third and the fourth zones have substantially a surface of the same area. Diffraction plate (1) according to any one of claims 4 and 5, further comprising at least two centering elements (26) making it possible to position the diffraction plate in a predefined position on a mount. Diffraction plate (1) according to any one of claims 4 to 6, in which the first direction is horizontal. Diffraction plate (1) according to any one of Claims 5 to 7, in which the second zone (4), the third (5) and the fourth (6) zones have the shape of an angular portion of a ring (7); said ring having as its center the center of the first zone (3), and in which the second (4), the third (5) and the fourth (6) zones surround the first zone (3). Diffraction plate (1) according to any one of Claims 5 to 8, in which the said predefined angle is between 50° and 70° and is preferably equal to 60°. Optical system (40) comprising an optical device (8) having an optical reference axis (13) and a diffraction plate (1), characterized in that the diffraction plate is shaped according to one of Claims 4 to 8, and in that the optical device (8) comprises:
- a light source (32) capable of emitting a light beam (14) having a plane wavefront and propagating along the optical axis;
- a mounting device (30) extending parallel to the optical axis (13), said mounting device (30) comprising a mount (12) having at least two complementary centering elements (34), a lens (9 ) arranged on the optical axis (13), a set of sensors (10) capable of acquiring a diffraction image, and an adjustable support (36) able to carry said set of sensors; said orientable support being adapted to move along the optical axis and to pivot around the optical axis (13), a vertical axis (Z) of inclination and a horizontal axis (Y) of inclination; the optical axis, the vertical inclination axis (Z) and the horizontal inclination axis (Y) forming a rectangular trihedron;said set of sensors (10) comprising pixels aligned along rows and columns.