FR2743636A1 - Optical reflector, especially for vehicle rear view mirror - Google Patents

Abstract

The reflector consists of a reflective surface (4) formed by a convex mirror which is combined with a plano-concave lens (1) so that the concave surface of the lens coincides with the reflective surface of the mirror. The plano-concave lens is made from a material with a refraction index of over 1.4 and selected from optical glass or optical polymers such as polystyrene, polycarbonate and polymethyl methacrylate. The reflective surface of the mirror can be produced by metallising the concave surface of the lens, and the mirror's radius of curvature is between 200 and 400 mm.

Description

REFLECTIVE OTIC DEVICE, PARTICULARLY INTENDED FOR
USED AS A MIRROR
Technical field
The invention relates to the field of optics, and more specifically to the manufacture of reflective devices such as mirrors, used in particular on various types of vehicles such as automobiles, trucks or motorcycles, but also on fixed installations.

Previous techniques
In a known manner, all vehicles are equipped with reflecting devices, commonly called mirrors, which allow the driver to perceive visual information on what is happening to the career of his vehicle, and more precisely in the direction opposite to that of his field of natural vision.

 In a very widespread way, the mirrors are generally constituted by a plane mirror. The advantage of flat mirrors is to avoid image distortion. Unfortunately, the accessible field of view is relatively small, typically of the order of 30, and the rear lateral areas of the vehicle remain out of reach of the driver. These hidden areas called "dead angle" are the cause of many accidents.

 To eliminate this dead angle, it has been proposed to associate two flat mirrors to form a dihedron. In this way, the rearview mirror gives two juxtaposed images of two different fields. Needless to say, this association increases the likelihood of confusion on the part of the driver and is therefore not fully satisfactory.

 It has also been proposed to give the reflective surface a convex, generally spherical shape. This solution makes it possible to increase the opening of the field of view. Indeed, the image formed by a convex mirror is a virtual image reduced in a ratio depending on the focal length of the mirror. The smaller the radius of curvature of the mirror, the shorter the focal length, and hence the higher the viewing angle. Unfortunately, if this type of mirror gives a correct image in the central area, on the other hand, the images of the peripheral zones undergo a distortion all the greater as the radius of the mirror is small, so that the field of vision is widened. In other words, the accessible side areas are highly deformed and difficult to exploit.

 To overcome this drawback, it has been proposed to give the convex surface an almost ellipsoidal aspherical profile. This solution effectively reduces the phenomena of distortion but is difficult to manufacture and is therefore not economically interesting.

 Furthermore, the patent CN 92.104226 describes a spherical mirror in which are carved a plurality of concentric annular sectors. These sectors form cone portions whose opening angles are different. The assembly behaves like a mirror whose focal length is a function of the distribution of the opening angles. These are chosen to limit the phenomena of distortion. Unfortunately, the non-continuous juxtaposition of the reflective zones gives an image of poor quality.

 The invention aims to overcome these disadvantages.

 The problem to be solved by the invention is that of widening the field of view in conjunction with a limitation of the distortion effects.

Presentation of the invention
The invention therefore relates to a reflective optical device, intended in particular to be used as a rearview mirror, of the type comprising a spherical reflecting surface forming a convex mirror.

 This device is characterized in that the convex mirror is associated with a plane-concave lens whose concave surface coincides with the reflecting surface of the convex mirror.

 In other words, the convex reflecting face is immersed in another medium than the surrounding air. In this way, the rays that form the image pass twice the interface between the plane-concave lens and the surrounding air. According to the geometry of this lens and n its refractive index, the focal length of the set is divided by n2 with respect to the focal length of a convex mirror alone, in the paraxial hypothesis.

 In other words, the invention consists in associating a spherical mirror with a transparent medium to modify the apparent curvature of this mirror and thus limit the effects of peripheral distortion. This combines the ease of manufacture of simple surfaces (flat and spherical) with improved performance in visual field and distortion.

 To increase the field of view sufficiently, the refractive index of the material constituting the plano-concave lens greater than 1.4 is chosen. In this way, in the paraxial approximation, the focal length is reduced by at least a factor of 2 relative to a spherical mirror alone.

Advantageously, the material constituting the plano-concave lens is chosen from the group comprising:
- optical glass,
optical polymers such as, for example, polystyrene, polycarbonates or polymethyl methacrylate.

 In practice, the reflecting surface of the convex mirror is obtained by metallization of the concave surface of the plano-concave lens.

In other words, the mirror is made by vapor deposition or electro-deposition of an aluminum or silver film.

 In a preferred form used for vehicle mirrors, a good compromise is achieved between the dimensions of the mirror, the field of view obtained and the materials used for the plankone lens, if the radius of curvature of the convex mirror is between 200 and 400 mm.

Brief description of the drawings
The way in which the invention can be realized and the advantages which result therefrom will emerge more clearly from the exemplary embodiment which follows, with the aid of the appended figures.

 Figure 1 is a cross section of a rear view mirror according to the invention.

FIG. 2 is a comparative graph showing the variation of the focal length and the angle of vision as a function of the aperture angle, for a convex mirror alone and for a mirror according to the invention.
FIG. 3 is a schematic sketch illustrating the distortion observed on a convex mirror and on a mirror according to the invention
FIG. 4 is a comparative graph showing the variation of the degree of distortion as a function of the diameter of the mirror, for a convex mirror and for a mirror according to the invention.

Way of realizing the invention
As already stated, the invention relates to an optical device that can be advantageously used as a rearview mirror in a vehicle or fixed station.

 The constitution of a mirror according to the invention is illustrated in Figure 1. Thus, the one consists of a plane-concave lens (1) having its flat face (2) in the direction of the user. The concave face (3) receives a reflective metal film (4) which thus forms a convex mirror. Of course, the invention also covers variant embodiments in which the lens is directly formed or cast on a pre-existing convex mirror.

 In practice, the lens (1) is made of a material such as glass or optical polymers such as polystyrene, polymethylmethacrylate, polycarbonates, or any other similar organic glass. This material is chosen for its mechanical strength, insensitivity to heat and especially its transparency and its refractive index (n). Typically, that is greater than 1.4 and preferably 1.5.

 Geometrically, the concave surface (3) has a center of curvature materialized by the point (C). The concave surface (3) is in fact a spherical cap with a diameter (A), depth (s) and whose vertex is referenced by the point (O). The axis of revolution (OC) of the cap is called the axis of the mirror. The opening angle e corresponds to the angle measured between a point (B) of the periphery of the cap and the axis OC.

Moreover, the thickness of the lens (1) in its thinnest zone is equal to 6. This thickness is optically inert and has the sole purpose of solidifying the lens-mirror assembly.

To understand the advantages of the invention, it is necessary to recall some general principles on the operation of a simple convex mirror. Thus, the focal length (f) separating the point O from the focus F, defined by the point where the rays parallel to the axis OC converge, is a function of the radius R and the opening angle o by the following formula

In the paraxial approximation, that is to say considering only the rays slightly inclined with respect to the optical axis OC, e is weak and the formula is simplified to give: f (B) 2 (2)
The accessible field of view a is therefore included inside the cone of vertex F and passing through the periphery of the spherical cap. n is therefore calculated by the following formula:

<tb> (2.f (H) <SEP>) <SEP> Arca "/ z <SEP> A <SEP> (3)
<tb> where A is the diameter of the spherical cap.

 Regarding the mirror according to the invention, the combination of the spherical mirror (4) with the characteristic planconcave lens (1) makes it possible to modify the optical characteristics in surprising proportions.

In general, the law of refraction teaches that an object situated in a medium of index n, at a distance (dl) from the interface with the air, appears as closer to the observer located in the air. More precisely, the distance at which the object appears is dl / n. In the case of the invention, the reflecting surface is located at a variable distance from the flat surface forming an interface with the air. In this way, the image of this surface is an ellipsoid (5) of center C 'appearing in dashed lines. The distance between each point and the center C 'can be expressed by the following formula:

Thus, the focal point F 'of the complete system is determined by calculation and the focal length OF satisfies the following formula:

This formula is simplified in the paraxial approximation and the focal length is then expressed by: f () R (6)
Thus, it is observed that the focal length is divided by a factor n2 with respect to the case of the simple spherical mirror. This ratio is typically greater than 2.4 in the case of the use of an optical polymer of polystyrene, polycarbonate or polymethyl methacrylate type whose refractive index is 1.55.

 This reduction in the focal length results in an enlargement of the viewing angle α, which constitutes one of the essential advantages of the invention.

 The curves in Figure 2 illustrate this advantage. These curves were plotted for a spherical mirror 340 mm radius, and for a mirror according to the invention having the same reflecting surface associated with a lens made of a material of equal refractive index val, 55.

 In a first set of curves giving the focal length f (o) as a function of the opening angle e of the mirror, it is observed that the focal length (face) of a mirror according to the invention is substantially less than the half of the focal length (fMCC) calculated for a convex mirror alone.

 This is reflected in the second set of curves showing the angle a (e) of the field of view as a function of the opening angle e of the mirror. Thus the field aMci accessible with a mirrored mirror mirror. Thus the aMCI field accessible with a rearview mirror according to the invention is almost twice that of aMCC a spherical mirror alone. Thus, if it is accepted that an angle of 75 "is necessary to eliminate blind spot problems, it is observed that the mirror according to the invention has an opening angle O less than half that of a spherical mirror alone. This has a direct influence on the thickness of the optical assembly.

 Another problem that the invention seeks to solve is that of limiting the distortion effects observed at the periphery of the images.

The origin of these phenomena lies in the fact that the focal length (f), outside the paraxial approximation, is a function of the angular position e of the object with respect to the optical axis. There is therefore a difference between the position calculated according to the paraxial approximation and the application of the precise formula. However, the shorter the focal length, the greater the distortion. It is therefore conceivable that the increase in the field of vision causes a greater distortion.

 This difference is illustrated in FIG. 3 for a spherical mirror alone and for a mirror according to the invention. The rectangle (10) calculated by the paraxial approximation is actually deformed to appear as a quadrilateral with the sides curved towards the outside. Disregarding the reduction ratios which, as we have seen above, are in a ratio n2, the image (11) obtained by the mirror according to the invention is less deformed than that (12) generated by a mirror spherical alone.

 This is quantified by applying the formulas above and is visualized on the curves of FIG.

Each curve gives λx = x0 x 100% as a function of the diameter A of the mirror xO with:
-xg the size of the image calculated by the application of formulas (2) and (6), in the paraxial approximation, - and x the size of the image calculated by the application of formulas (1) and ( 5)
Thus, the AMCI curve shows that for a diameter of the order of 150 mm, the distortion is of the order of two orders of magnitude less than for a spherical mirror alone AMCC
It follows from the above that the mirror according to the invention has multiple advantages over existing mirrors and in particular spherical mirrors. Indeed, the field of vision is at least increased by a factor of two. At the same time, peripheral distortion phenomena are reduced in the same proportions. In summary, the invention makes it possible to combine what is unattainable with a spherical mirror alone, namely the increase of the field of view and the reduction of the distortion. Thus, for a given viewing angle, the thickness of the mirror is significantly lower in the case of the invention, which facilitates the implantation of such mirrors. Finally, the useful surfaces are flat and spherical, that is to say, easy to manufacture.

Claims (4)

REVINDICATIONS 1 / Reflective optical device, intended in particular for use as a rear-view mirror, of the type comprising a spherical reflecting surface (4) forming a convex mirror, characterized in that the convex mirror (4) is associated with a plano-concave lens (1) whose concave surface (3) coincides with the reflecting surface (4) of the convex mirror. 2 / Apparatus according to claim 1, characterized in that the refractive index of the material constituting the planconcave lens (1) is greater than 1.4. 3 / Apparatus according to claim 1, characterized in that the material constituting the plano-concave lens (1) is selected from the group consisting of: optical glass, optical polymers such as polystyrene, polycarbonates and polymethyl methacrylate. 4 / Apparatus according to claim 1, characterized in that the reflective surface (4) of the convex mirror is obtained by metallization of the concave surface (3) of the plankoncave lens (1). 4 / Apparatus according to claim 1, intended to serve as vehicle rearview mirror, characterized in that the radius of curvature of the convex mirror (4) is between two hundred (200) and four hundred (400) millimeters.