JPH0618336Y2 - Slit image forming device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a slit image forming apparatus for forming a slit image at an arbitrary position.

<Prior art> Conventionally, the slit-shaped light flux used for measuring the tilt angle by an optical lever, after collimating the light flux emitted from the light source with a collimator lens, irradiates the slit, and the light flux that has passed through the slit is used as a lens. A method of forming an image with a system to obtain a slit-shaped light beam on a predetermined focal plane, a method of forming a parallel light beam into a slit shape by using one convex cylindrical lens, and the like have been used.

<Problems to be Solved by the Invention> However, in the method of obtaining a slit-shaped image using the above-described slit, only the light that has passed through the narrow slit reaches the focal plane. Obtaining an image is difficult.

On the other hand, in the method using one convex cylindrical lens, while a high-brightness slit-shaped image is obtained, the focal length determined by the convex cylindrical lens is constant, so that the focal plane depending on the convex cylindrical lens used It is necessary to change the distance or change the convex cylindrical lens according to the distance to the image plane. In addition, since the focal length of commercially available long-focus cylindrical lenses is about several tens of centimeters, when a focal length that exceeds this focal length is required, a slit-shaped image obtained with the cylindrical lens is effectively acquired. Can not.

Further, an apparatus for extending a parallel light flux having a circular cross section in one direction by using two convex cylindrical lenses to obtain a light flux having a spindle cross section is disclosed in, for example, Japanese Patent Application No. 57-120763 (Japanese Utility Model Application No. 59-25557). It is disclosed, and when this spindle-shaped parallel light flux is applied to the image forming surface, a slit-shaped image can be obtained. According to this method, since a slit or the like is not used, it is possible to obtain a slit-shaped image with relatively high brightness.

However, if the arrangement state of both cylindrical lenses set based on the focal lengths of these two convex cylindrical lenses is changed, the slit length of the slit-shaped image will change, and a predetermined slit length can be obtained. In order to set such, it is necessary to keep the position of the biconvex cylindrical lens strictly constant or to adjust the distance to the image plane at any time, so that the slit length of the slit image is constant. It's not easy to do.

Moreover, since the slit width of the slit-shaped image generated by using the two cylindrical lenses is constant, the slit width is narrowed to increase the brightness, or conversely, the slit width is increased to decrease the brightness. I can't
There is also a problem that a desired slit image cannot always be obtained.

Therefore, the present invention provides a slit-shaped image forming apparatus capable of easily obtaining a slit-shaped image having a constant slit length and easily adjusting the slit width of the slit-shaped image. To aim.

<Means for Solving the Problems> In order to solve the above problems, a slit image forming apparatus according to the present invention includes a parallel light beam acquisition unit (for example, a light source and an optical system 1) capable of emitting a parallel light beam, Having a parallel light flux from the parallel light flux acquisition means, having a convex cylindrical lens (2) in which the axial direction of the radius of curvature coincides with the optical axis, and a focal length equal to or less than the absolute value of the focal length of the convex cylindrical lens, A concave cylindrical lens (3) that receives the light flux from the convex cylindrical lens and has the axial direction of the radius of curvature coincident with the optical axis, and a lens interval adjusting means (for example, a relative interval between the convex cylindrical lens and the concave cylindrical lens) (for example, And a concave cylindrical lens moving mechanism 4).

<Operation> When the parallel light flux emitted from the parallel light flux acquisition means passes through the convex cylindrical lens, one direction corresponding to the cylindrical surface becomes a light flux having a constant width. Then, by changing the relative distance between the convex cylindrical lens and the concave cylindrical lens by the lens distance adjusting means, it is possible to variably adjust the slit width of the slit image on the image plane where the light flux passing through the concave cylindrical lens reaches.

<Embodiment> Next, an embodiment of the slit image forming apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

The slit-shaped image forming apparatus according to the configuration of FIG. 1 is, for example, for obtaining a slit-shaped image that is long in the vertical direction, and makes the light incident from the light source a parallel light flux having a predetermined diameter by the optical system 1. A convex cylindrical lens 2 and a concave cylindrical lens 3 which are appropriately larger than the diameter of the parallel light flux are arranged in parallel at appropriate intervals, and the concave cylindrical lens 3 is moved forward and backward while maintaining the parallelism of both cylindrical lenses 2 and 3. A concave cylindrical lens moving mechanism 4 that can be moved is provided.

In the present embodiment, the light source and the optical system 1 constitute a parallel light flux acquisition means so that a desired parallel light flux can be emitted. Further, as shown in FIG. 1, the convex cylindrical lens 2 receives the parallel light flux from the optical system 1, and the axial direction of the radius of curvature coincides with the optical axis, and the concave cylindrical lens 3 is different from the convex cylindrical lens 2 described above. And the axial direction of the radius of curvature is aligned with the optical axis.

On the other hand, FIG. 2 shows the positional relationship between the convex cylindrical lens 2 and the concave cylindrical lens 3 in FIG. 1 from the side, and F ₁ in FIG. 2 is the rear side of the convex cylindrical lens 2 (consolidated). the image plane side) focal point, F ₂ is the front side of the concave cylindrical lens 3 (optical system 1 side) focal point,
Reference character F denotes a convergence point determined by the positional relationship between the cylindrical lenses 2 and 3, respectively.

In this embodiment, the concave cylindrical lens 3
In the range of the focal length of the convex cylindrical lens 2, the concave cylindrical lens 3 is positioned so that the convergence point F is located behind
The concave cylindrical lens moving mechanism 4 is configured to move back and forth. However, since the parallel light flux is supplied to the convex cylindrical lens 2, even if the concave cylindrical lens 3 is fixed at a predetermined position and the distance between the convex cylindrical lens 2 and the optical system 1 is changed, the convergence point F
The position of can be changed arbitrarily. That is, it suffices to have a lens interval adjusting means for adjusting the relative interval between the convex cylindrical lens 2 and the concave cylindrical lens 3, and for example, the lens interval may be adjusted by a convex cylindrical lens moving mechanism.

Further, as shown in FIG. 2, since the cylindrical surfaces of the convex and concave cylindrical lenses 2 and 3 are arranged so that the curvature is constant with respect to the vertical direction, the parallel light flux contracts in the vertical direction. The vertical length of the image formed by the light beam irradiated through the slit image forming apparatus is constant regardless of the position of the image forming surface. That is, the slit length, which is the vertical length of the image generated on the image plane, is kept constant.

In the present embodiment, the cross section of the parallel light beam emitted from the optical system 1 is circular and a slit-shaped image having the same diameter as the parallel light beam is obtained.
If a vertical width is set to be equal to a desired slit length by interposing a slit or the like between the convex cylindrical lens 2 and the convex cylindrical lens 2, it is extremely easy to change the slit length to an arbitrary slit length. In such a case, the light source, the optical system 1, the slit, etc. are made to function as the parallel light flux acquisition means.

Next, the relationship between the relative distance between the convex cylindrical lens 2 and the concave cylindrical lens 3 and the convergence point F will be described with reference to FIG. Note that FIG. 3 is a view showing the positional relationship between the convex cylindrical lens 2 and the concave cylindrical lens 3 from above.

In this figure, f ₁ is the focal length of the convex cylindrical lens 2, −f ₂ is the focal length of the concave cylindrical lens 3,
X indicates the distance between the two cylindrical lenses 2 and 3, and D indicates the distance from the concave cylindrical lens 3 to the converging point F (hereinafter referred to as the working distance). Note that f ₁ and f ₂ are both positive values, but the focal point F ₂ of the concave cylindrical lens 3 exists in the direction opposite to the focal point F ₁ of the convex cylindrical lens 2, so the focal length of the concave cylindrical lens 3 is It is a negative value.

Further, when the thicknesses of the convex cylindrical lens 2 and the concave cylindrical lens 3 are made to be negligibly small, and the thin-wall approximation is performed, the working distance D is D = f ₂ (f ₁ −X) / (f ₂ −f ₁ + X) ...

Under the above conditions, when a converging point occurs behind the concave cylindrical lens 3 (D> 0), the converging point is obtained at the maximum and minimum limit values of the working distance D, that is, both infinity and zero. When a condition is put in and a condition of X satisfying this condition is obtained, f ₁ −f ₂ ≦ X ≦ f ₁ (however, f ₂ ≦ f ₁ ) ... The equal sign in the above equation corresponds to the limit value of infinity or zero.

From the above formula, the distance f ₂ from (f ₁ −f ₂ ) to f ₁
If only X has a movable range, it can be seen that D changes greatly from 0 to infinity. This means that the slit-shaped image forming apparatus can change the working distance D greatly by a small movement of X as f ₂ is smaller than f ₁ , and conversely, as f ₂ gets closer to f ₁ , the movement distance of X becomes larger. The slit-shaped image forming apparatus is capable of performing precise position adjustment by reducing the amount of change in the working distance D.

That is, if the concave cylindrical lens 3 having a focal length equal to or less than the absolute value of the focal length of the convex cylindrical lens 2 is used and the lens distance X is appropriately adjusted by the lens distance adjusting means such as the concave cylindrical lens moving mechanism 4, the working distance is It is possible to arbitrarily change D, and it is possible to arbitrarily change the slit width of the slit image projected on the image plane. Therefore, if the lens interval X is adjusted so that the converging point is located on the image plane, it is possible to obtain a slit-shaped image having the smallest slit width and the highest brightness. Of course, it is also possible to obtain a slit-shaped image having an arbitrary slit width on the image plane by simply adjusting the lens interval X.

As described above, according to the slit image forming apparatus of the present invention, the slit length is determined by the parallel light flux obtained by the parallel light flux acquisition means, and the slit width corresponding to the interval X between the convex cylindrical lens 2 and the concave cylindrical lens 3. Since it is possible to obtain a slit-shaped image of, it is possible to easily obtain a slit-shaped image of a constant slit length, it is possible to easily adjust the slit width of the slit-shaped image, conventional slit-shaped image There is no need to replace the lens or finely adjust the distance from the lens to the image plane as in the image forming apparatus, which is of great practical value.

Here, an example in which f ₁ = f ₂ = f will be described in detail. Substituting this relationship into the above formula, D = f ² / X−f. FIG. 4 shows f = 0.1 [m], f = 0.2 [m], f
= 0.5 [m], f = 1.0 [m]
6 is a characteristic curve diagram of working distance D with respect to FIG.

Further, the ratio dD / dX of the change amount of the working distance D to the minute change of X (hereinafter, referred to as the movement rate of the convergence point) is dD / dX =-(f / X) ² ... FIG. 5 shows that f = 0.1 [m], f = 0.2 [m], f
= 0.5 [m], f = 1.0 [m]
FIG. 6 is a characteristic curve diagram of a moving rate dD / dX of a convergence point with respect to

From FIGS. 4 and 5, it is possible to obtain various characteristics according to the set value of the focal length f even when the convex cylindrical lens 2 and the concave cylindrical lens 3 having the same focal length are used. I understand. Therefore, according to the slit image forming apparatus of the present invention, not only can the working distance D be appropriately set according to the focal lengths of the cylindrical lenses 2 and 3, but also the movement rate of the convergence point according to the purpose. It can be used as a slit-shaped image forming device.

For example, under the condition of f ₁ = f ₂ = f, D = 5
[M], dD / dX = 100, when designing a slit-shaped image forming apparatus that can obtain a relatively large change in D by reducing the variable range of X, f =
It is calculated as 0.55 [m] and X = 0.5 [m].

<Effect of the Invention> As described above, according to the slit image forming apparatus of the present invention, when the parallel light flux emitted from the parallel light flux acquisition means passes through the convex cylindrical lens, one direction corresponding to the cylindrical surface is obtained. Is a light beam having a constant width, and the slit width of the slit-shaped image on the image plane where the light beam passing through the concave cylindrical lens reaches by changing the relative distance between the convex cylindrical lens and the concave cylindrical lens by the lens interval adjusting means. Can be adjusted.

That is, with the slit length determined by the parallel light flux obtained from the parallel light flux acquisition means, it is possible to obtain a slit-shaped image having a slit width corresponding to the interval between the convex cylindrical lens and the concave cylindrical lens, so that a slit-shaped image having a constant slit length is obtained. It can be easily obtained, and the slit width of the slit image can be easily adjusted,
The slit-shaped image forming apparatus has great practical value.

[Brief description of drawings]

FIG. 1 is a perspective view showing a schematic configuration of a slit-shaped image forming apparatus according to the present invention, and FIG. 2 is an explanatory view showing the arrangement state of convex cylindrical lenses and concave cylindrical lenses on the side and the focal points of both lenses. FIG. 3 is an explanatory view showing the arrangement state of the convex cylindrical lens and the concave cylindrical lens in the upper part, the focal point of both lenses and the convergence point of the light passing through both lenses, and FIG. 4 is a characteristic curve showing the relationship between the lens interval and the working distance. FIGS. 5A and 5B are characteristic curve diagrams showing the relationship between the lens interval and the movement rate of the convergence point. In the figure, 1 is an optical system, 2 is a convex cylindrical lens, 3 is a concave cylindrical lens, and 4 is a concave cylindrical lens moving mechanism.

Claims (1)

[Scope of utility model registration request] 1. A parallel light flux acquisition means capable of emitting a parallel light flux, and a parallel light flux received from the parallel light flux acquisition means,
A convex cylindrical lens whose axial direction of the radius of curvature coincides with the optical axis, and a focal length which is equal to or less than the absolute value of the focal length of the convex cylindrical lens, receives a light beam from the convex cylindrical lens, and has an axial direction of the radius of curvature. A slit-shaped image forming apparatus, comprising: a concave cylindrical lens having the optical axis aligned with the optical axis; and a lens interval adjusting unit that adjusts a relative interval between the convex cylindrical lens and the concave cylindrical lens.