JP6137839B2 - Receiving optical system - Google Patents

Description

  The present invention relates to a receiving optical system that receives a weak light beam emitted from a distant point-like object and detects a signal from the light beam.

For example, Patent Document 1 below discloses an optical pickup lens that uses single-wavelength ultraviolet light, and this optical pickup lens is a single convex lens while achieving a large numerical aperture of 0.8 or more. In order to correct spherical aberration and coma, both surfaces of the lens are composed of 16th-order aspheric surfaces.
However, it is known that the aspherical shape of the lens increases the manufacturing difficulty and increases the manufacturing cost as the asphericity increases.

Examples of products that use optical pickup lenses include DVDs and Blu-ray disc drives. If the number of products produced is several million a year, the optical pickup lenses can be manufactured by molding with a precision mold. It seems to be done.
The manufacturing cost of a precision mold having a transfer surface with strong asphericity is high, but the manufacturing cost of the optical pickup lens can be reduced by the mass production effect.
However, in the case of a product for which a large number of products cannot be expected at all, mass production effects cannot be expected, and the unit cost of manufacturing an optical pickup lens cannot be suppressed.

Patent Document 2 below discloses a projection optical system (for example, a projection optical system using 23 lenses) of an exposure apparatus that uses single-wavelength ultraviolet light.
In this projection optical system, in order to ensure a large image-side numerical aperture of about 0.8 and correct aberrations satisfactorily while ensuring the throughput of the entire optical system, the thickness of the lenses constituting the optical system is set to a predetermined value. It is determined by the conditional expression.

In the projection optical system disclosed in Patent Document 2, since the desired optical performance can be ensured by increasing the number of lenses, a higher-order aspheric lens is used as in Patent Document 1. There is no need. For this reason, it is possible to use a spherical lens with a low manufacturing difficulty and a relatively low manufacturing unit price.
However, the increase in the number of lenses increases the man-hours required for assembly adjustment of the optical system, so even if the cost of the lens alone can be reduced, the cost of the entire optical system may not be reduced.
In addition, the number of lenses to be used may be limited due to dimensional restrictions required for the optical system.

JP 2009-295277 A (paragraph numbers [0045] to [0048]) JP 2010-91751 A (paragraph number [0006])

  Since the conventional receiving optical system is configured as described above, in order to correct spherical aberration and coma aberration while achieving a large numerical aperture, a high-order aspherical lens or a large number of manufacturing difficulty is high. It is necessary to use a lens. Therefore, there is a problem that the manufacturing cost becomes high. In addition, there is a problem that the number of usable lenses is limited due to dimensional restrictions required for the optical system, and aberrations may not be sufficiently corrected.

  The present invention has been made to solve the above-described problems, and it is sufficient to achieve a large numerical aperture without using a high-order aspherical lens and a large number of lenses that are difficult to manufacture. An object is to obtain a receiving optical system capable of correcting aberrations.

The receiving optical system according to the present invention includes an aperture stop portion for reducing a diameter of a light beam emitted from a point-like object, and a conic surface having a convex incident surface on which a light beam whose diameter is reduced by the aperture stop portion is incident. A receiving lens having a flat emitting surface for emitting the light beam, and a signal detector for receiving a light beam emitted from the emitting surface of the receiving lens and detecting a signal from the light beam. And the signal detector are filled with a medium having a refractive index larger than air, and the conic coefficient at the receiving surface of the receiving lens has a focal length of the receiving lens, a refractive index of the receiving lens, and a refractive index larger than that of air. It is determined by the refractive index of the medium, the thickness of the medium, and the imaging spot diameter and numerical aperture of the light beam in the signal detector corresponding to the desired signal-to-noise ratio .

  According to the present invention, since the space between the output surface of the receiving lens and the signal detector is filled with a medium having a refractive index larger than that of air, a high-order aspherical lens having a high manufacturing difficulty or There is an effect that aberrations can be sufficiently corrected while achieving a large numerical aperture without using a large number of lenses.

It is a block diagram which shows the receiving optical system by Embodiment 1 of this invention. It is a schematic diagram which shows the receiving optical system which images the point light source of a distant object. If the refractive index of the image field medium 8 is n ₃ = 1.0, it is an explanatory view showing the lens data for correcting the spherical aberration near the diffraction limit. If the refractive index of the image field medium 8 is n ₃ = 1.5, it is an explanatory view showing the lens data for correcting the spherical aberration near the diffraction limit. It is a block diagram which shows the example of a package of a receiving optical system. It is a schematic diagram which shows the signal detection example of the signal detector 9 of the receiving optical system by Embodiment 2 of this invention. It is explanatory drawing which shows the lens data at the time of calculating | requiring the conic coefficient k which leaves spherical aberration from Formula (5) so that the imaging spot diameter p on an optical axis may be set to 100 micrometers. It is a top view which shows the light-receiving surface of the signal detector 9 of the receiving optical system by Embodiment 3 of this invention. It is explanatory drawing which shows the imaging spot characteristic of the receiving lens. It is a top view which shows the light-receiving surface of the signal detector 9 of the receiving optical system by Embodiment 4 of this invention. It is explanatory drawing which shows the imaging spot characteristic of the receiving lens.

Embodiment 1 FIG.
1 is a block diagram showing a receiving optical system according to Embodiment 1 of the present invention.
In FIG. 1, a point-like object 1 is a point-like light source on an optical axis 3 in a distant object, and emits weak light (light beam).
The point object 2 is a point light source outside the optical axis 3 in a distant object, and emits weak light (light beam).
The bandpass filter 4 is an optical component that separates light of a desired wavelength contained in the light flux emitted from the point-like objects 1 and 2.

The aperture stop 5 is an optical component that reduces the radius of a light beam having a desired wavelength dispersed by the bandpass filter 4 to R.
By reducing the diameter of the light beam emitted from the pointed object 1 by the aperture stop unit 5, the outermost light ray of the light beam becomes as indicated by reference numeral 6.
The receiving lens 7 is an optical component that forms an image of the light beam emitted from the point-like objects 1 and 2, and the incident surface on which the light beam whose diameter is reduced by the aperture stop 5 is a convex conic surface, The exit surface that emits the light beam is a flat surface.

The signal detector 9 is a processor that receives a light beam emitted from the emission surface of the receiving lens 7 and detects a signal from the light beam.
Note that images 1 ′ and 2 ′ of the point-like objects 1 and 2 are formed on the light receiving surface of the signal detector 9.
In the receiving optical system of FIG. 1, a medium having a refractive index larger than air (hereinafter referred to as “image field medium 8”) is filled between the exit surface of the receiving lens 7 and the signal detector 9.

Next, the operation will be described.
When the light beams emitted from the point-like objects 1 and 2 are incident on the band-pass filter 4, the light having a desired wavelength contained in the light beams is dispersed by the band-pass filter 4.
The light beam having a desired wavelength dispersed by the bandpass filter 4 is narrowed by the aperture stop 5, and the light beam having a radius R reaches the incident surface of the receiving lens 7.

When the receiving lens 7 having a convex conic surface and a flat exit surface is incident on a light beam whose diameter is reduced by the aperture stop 5, the light beam is imaged on the light receiving surface of the signal detector 9. To do.
The image 1 ′ is an image of the point object 1, and the image 2 ′ is an image of the point object 2.
However, in the receiving optical system of FIG. 1, the space between the exit surface of the receiving lens 7 and the signal detector 9 is filled with an image field medium 8 having a refractive index n ₃ greater than air and having a thickness d ₃ .
For this reason, the light beam emitted from the emission surface of the receiving lens 7 is imaged on the light receiving surface of the signal detector 9 after passing through the image field medium 8.

The signal detector 9 receives the image 1 ′ of the point-like object 1 imaged by the receiving lens 7 and detects a signal (for example, a luminance signal or a color signal) corresponding to the image 1 ′.
The signal detector 9 receives the image 2 ′ of the point-like object 2 formed by the receiving lens 7 and detects a signal (for example, a luminance signal or a color signal) corresponding to the image 2 ′.

式（１）において、ｈは受信レンズ７の開口半径、ｒは受信レンズ７の入射面（凸面）における近軸曲率半径、ｋはコーニック係数、ａ₄は４次の非球面係数、ａ₆は６次の非球面係数、ａ_iは高次（ｉ次）の非球面係数である。
なお、式（１）で与えられる非球面形状は、コーニック係数ｋ及び高次非球面係数ａ_iの絶対値が大きくなる程、非球面性が強くなり、製造難易度が上がる。 Here, the aspherical shape on the incident surface (convex surface) of the receiving lens 7 is given by the following equation (1).

In equation (1), h is the aperture radius of the receiving lens 7, r is the paraxial radius of curvature on the incident surface (convex surface) of the receiving lens 7, k is the conic coefficient, a ₄ is the fourth-order aspheric coefficient, and a ₆ is A sixth-order aspheric coefficient, a _i, is a higher-order (i-order) aspheric coefficient.
Note that the aspheric shape given by the equation (1) increases in asphericity as the absolute values of the conic coefficient k and the higher-order aspheric coefficient a _i increase, and the manufacturing difficulty increases.

Next, the relationship between the amount of light that falls within the image 1 ′ and the image 2 ′ on the light receiving surface of the signal detector 9, the ray aberration generated in the receiving optical system, and the aspherical shape necessary for correcting the ray aberration will be described.
First, the numerical aperture NA, which is a parameter representing the amount of light of the images 1 ′ and 2 ′ on the light receiving surface of the signal detector 9, will be described.
FIG. 2 is a schematic diagram showing a receiving optical system for imaging a point light source of a distant object.
In the example of FIG. 2, the receiving optical system is filled with an image field medium having a refractive index n ₃ , and the light beam with the radius R ′ emitted from the point light source is narrowed to the radius R by the aperture stop, and the radius R Are incident on the receiving lens to form an image.
As apparent from FIG. 2, the light quantity of the image of the receiving lens increases as the radius R of the aperture stop increases as the focal length f is constant.

式（２）より、開口絞り部の半径Ｒが大きくなると、開口数ＮＡも大きくなり、開口数ＮＡが像の光量を示すパラメーターであることがわかる。 The numerical aperture NA, which is a parameter representing the light quantity of the image, is given by the following formula (2).

From equation (2), it can be seen that as the radius R of the aperture stop increases, the numerical aperture NA also increases, and the numerical aperture NA is a parameter indicating the light quantity of the image.

Next, the relationship between the numerical aperture NA and the light aberration generated in the receiving lens 7 will be described.
In the receiving optical system of FIG. 1, when the numerical aperture NA is increased, sin θ in Expression (2) increases.
The increase in sin θ means that the angle of refraction of the outermost ray 6 by the receiving lens 7 is increased, which causes an increase in ray aberration.
In order to correct this ray aberration, the aspherical shape given by the equation (1) is applied to the incident surface (convex surface) of the receiving lens 7. The larger the amount of ray aberration to be corrected, the more conic of the equation (1). The absolute value of the coefficient k and the higher-order aspheric coefficient a _i increases, and the asphericity becomes stronger.

Therefore, in order to reduce the amount of light aberration generated in the receiving lens 7 while maintaining a large numerical aperture NA and weaken the aspherical shape of the aspherical surface necessary for correcting the light aberration, sin θ in Expression (2) is used. Need to be small.
In order to reduce sin θ in equation (2), the refractive index n ₃ of the image field medium in equation (2) may be increased.
Therefore, in the receiving optical system of FIG. 1, the space between the exit surface of the receiving lens 7 and the signal detector 9 is filled with an image field medium 8 having a refractive index n ₃ larger than air.

In general, an image field medium of an imaging optical system such as a digital camera is air having a refractive index of 1.0. However, in the first embodiment, since the refractive index n ₃ is larger than that of air, the expression ( The sin θ of 2) becomes small. For this reason, it is possible to suppress the ray aberration generated in the receiving lens 7 as compared with the case where the image field medium is air, and as a result, the asphericity of the aspheric shape necessary for correcting the ray aberration is weakened. Manufacturing difficulty can be lowered.

Here, as the image field medium 8, for example, a “transparent gel-like sealing material for electronic parts” used for sealing the LED light emitting surface or the like can be used.
Further, when the signal detector 9 having no wiring is mounted on the light receiving surface of the detector (for example, a back-illuminated detector), a flat plate is formed on the output surface of the receiving lens 7 and the light receiving surface of the signal detector 9. Glass or resin may be adhered.

Next, an embodiment in which the image field between the emission surface of the receiving lens 7 and the signal detector 9 is air and a case where the image field is filled with a medium having a refractive index n ₃ larger than air will be described.
FIG. 3 shows an object distance s = ∞, a wavelength of 1.5 μm, a distance t = 0 between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7, a focal length f = 20 mm, and a numerical aperture NA = 0.6. In a receiving optical system (radius R of the aperture stop 5 = 12 mm) and the refractive index of the glass material of the receiving lens 7 = 1.8, spherical aberration is reduced when the refractive index of the image field medium 8 is n ₃ = 1.0. It is explanatory drawing which shows the lens data correct | amended to the diffraction limit vicinity.
FIG. 4 shows an object distance s = ∞, a wavelength of 1.5 μm, a distance t = 0 between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7, a focal length f = 20 mm, and a numerical aperture NA = 0.6. In a receiving optical system (radius R = 12 mm of the aperture stop 5) and glass material refractive index = 1.8 of the receiving lens 7, spherical aberration is reduced when the refractive index of the image field medium 8 is n ₃ = 1.5. It is explanatory drawing which shows the lens data correct | amended to the diffraction limit vicinity.

As shown in FIG. 3, when the refractive index of the image field medium 8 is n ₃ = 1.0, a parabolic (k = −1) -based sixth-order aspheric surface is necessary to correct spherical aberration. is there.
On the other hand, when the refractive index of the image field medium 8 is n ₃ = 1.5 as shown in FIG. 4, when correcting spherical aberration, a paraboloid is used without using a fourth-order or sixth-order aspheric term. Can be realized by using an ellipsoid (-1 <k <0) having a weak asphericity.
In the above example, correction of spherical aberration is shown, but the same effect can be obtained by correcting other ray aberrations.

As apparent from the above, according to the first embodiment, the space between the exit surface of the receiving lens 7 and the signal detector 9 is filled with the image field medium 8 having a refractive index n ₃ larger than air. Thus, it is possible to sufficiently correct the aberration while achieving a large numerical aperture NA without using a high-order aspherical lens or a large number of lenses that are difficult to manufacture.

Further, by filling the space between the output surface of the receiving lens 7 and the signal detector 9 with the image field medium 8 having a refractive index n ₃ larger than air, the following effects can be obtained.
When the numerical aperture NA of the receiving optical system is large and the image field is air, total reflection occurs when the outermost shell ray 6 exceeds the critical angle of the glass material used for the receiving lens 7, and the outermost ray 6. Cannot pass through the receiving lens 7 and cannot reach the signal detector 9. However, since the critical angle at the exit surface of the receiving lens 7 can be increased by filling with the image field medium 8 having a refractive index n ₃ larger than that of air, reception with a larger numerical aperture NA than in the case where the image field is air. An optical system can be realized.

Further, according to the first embodiment, since the output surface of the reception lens 7 is a flat surface, there is an effect of facilitating assembly of the reception optical system.
FIG. 5 is a configuration diagram showing a package example of the receiving optical system.
In FIG. 5, since the emission surface of the reception lens 7 is a flat surface, the emission surface of the reception lens 7 and the flat covering portion 12 of the lens barrel 11 can be brought into close contact with each other.
Therefore, the central axis of the lens barrel 11 and the optical axis 3 of the receiving lens 7 can be easily made parallel, and as a result, the signal detector 9 on the light receiving surface due to the inclination of the receiving lens 7 can be obtained. Image blurring can be made difficult to occur, and assembling is facilitated.
Further, since the output surface of the receiving lens 7 is a flat surface, a simple spacer having a hollow cylindrical shape can be sandwiched between the substrate 10 on which the signal detector 9 is mounted. The image field medium 9 can be sealed.

In the first embodiment, since the receiving lens 7 is a single convex lens made of one kind of glass material, chromatic aberration cannot be corrected.
When the light emitted from the pointed objects 1 and 2 that are distant objects has a wide wavelength width such as white light, it is necessary to perform spectroscopy to a wavelength width at which the chromatic aberration of the receiving lens 7 can be ignored. In the receiving optical system of FIG. 1, a bandpass filter 4 is used.

Embodiment 2. FIG.
In the second embodiment, a case will be described in which the light receiving surface of the signal detector 9 exists only in a small region near the optical axis 3 of the receiving optical system, like a single photodiode.
FIG. 6 is a schematic diagram showing a signal detection example of the signal detector 9 of the receiving optical system according to the second embodiment of the present invention. In FIG. 6, the same reference numerals as those in FIG.
In FIG. 6, a light detector having a luminance L emitted from a distant object passes through the bandpass filter 4, the aperture stop unit 5, the receiving lens 7, and the image field medium 8, and then is a signal detector composed of a large number of pixels. 9 shows an example in which a signal formed on image 9 and including a signal S and noise N is detected.

一方、信号検出器９で生じる雑音Ｎが、ほぼショットノイズのみとみなせる場合、信号対雑音比ＳＮＲは、下記の式（４）で与えられる。

If the area of one pixel in the signal detector 9 of FIG. 6 is A and the receiving lens 7 has no aberration, the signal S detected by one pixel is given by the following equation (3).

On the other hand, when the noise N generated in the signal detector 9 can be regarded as only shot noise, the signal-to-noise ratio SNR is given by the following equation (4).

When the signal detector 9 detects a signal, the signal amount of the signal to be detected is important, but the signal-to-noise ratio SNR in Expression (4) is also important.
When the imaging spot diameter p of the images 1 ′ and 2 ′ of the point-like objects 1 and 2 by the receiving lens 7 of FIG. 1 spreads due to the aberration and becomes larger than the pixel size of the signal detector 9, the signal-to-noise of equation (4) The specific SNR decreases.
For example, when the area formed by the imaging spot diameter p increases to n times the area A of one pixel in the signal detector 9, the signal-to-noise ratio SNR in Expression (4) decreases to 1 / √n.
However, if the signal-to-noise ratio SNR required in the receiving optical system may be 1 / √n of the value given by the equation (4), the imaging spot diameter p of the receiving lens 7 is equal to the pixel in the signal detector 9. The size for n pieces may be sufficient.

Therefore, the necessary imaging spot diameter p of the receiving lens 7 is determined from the desired signal-to-noise ratio SNR.
Since the desired signal-to-noise ratio SNR is smaller than the value given by Equation (4), if the imaging spot diameter p can be made larger than the area A of one pixel of the signal detector 9, the aberration of the receiving lens 7 remains. This means that the asphericity of the incident surface (convex surface) of the receiving lens 7 can be weakened.
Note that the signal-to-noise ratio SNR is desired. For example, in order to significantly separate the noise N and the signal S, at least the signal-to-noise ratio SNR needs to be 1 or more.

Here, when the signal detector 9 is a photodiode and the photodiode is on the optical axis 3 of the receiving optical system, the aberration to be corrected by the aspherical surface that is the incident surface (convex surface) of the receiving lens 7 is spherical aberration. It is.
The conic coefficient k of the incident surface (convex surface) of the receiving lens 7 necessary to leave the spherical aberration having the desired imaging spot diameter p is a value obtained by the following equation (5) or in the vicinity thereof. Value.

FIG. 7 shows an object distance s = ∞, a wavelength of 1.5 μm, a distance t = 0 between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7, a focal length f = 20 mm, and a numerical aperture NA = 0.6. In the receiving optical system in which the aperture stop 5 has a radius R = 12 mm, the glass material refractive index of the receiving lens 7 is 1.8, and the refractive index of the image field medium 8 is n ₃ = 1.5, the image is formed on the optical axis. It is explanatory drawing which shows the lens data at the time of calculating | requiring the conic coefficient k which leaves spherical aberration from Formula (5) so that the spot diameter p may be set to 100 micrometers.
It can be seen that the value of the conic coefficient k of FIG. 7 in which the spherical aberration remains is smaller than that of the conic coefficient k of FIG. 4 when the spherical aberration is corrected to the diffraction limit.

Embodiment 3 FIG.
In the third embodiment, a case will be described in which the reception optical system uses a signal detector 9 in which long light receiving surfaces are arranged at regular intervals.
FIG. 8 is a plan view showing the light receiving surface of the signal detector 9 of the receiving optical system according to Embodiment 3 of the present invention.
In the signal detector 9 of FIG. 8, a plurality of long light receiving surfaces 21 are arranged at regular intervals, and there is a region 22 having no light receiving sensitivity.

Since the angle of view related to the image 1 ′ of the point-like object 1 and the angle of view related to the image 2 ′ of the point-like object 2 are different from each other, as shown in FIG. The position of the 2 ′ imaging spot is different. In the example of FIG. 9, 23 is an imaging spot of image 1 ′, and 24 is an imaging spot of image 2 ′.
Therefore, when the signal detector 9 of FIG. 8 is used, as shown in FIG. 9, the imaging spot diameter p has a constant value equal to or larger than the arrangement interval of the long light receiving surfaces 21 regardless of the field angle w. The ray aberration of the receiving lens 7 to be corrected at this time is coma aberration depending on the angle of view w.
On the other hand, the spherical aberration needs to remain in order to obtain the imaging spot diameter p.

In the first and second embodiments, the aperture stop portion 5 is disposed on the incident surface (convex surface) side of the receiving lens 7, but according to the aberration theory, in the receiving optical system of FIG. When the distance between the diaphragm unit 5 and the incident surface (convex surface) of the receiving lens 7 is t = 0, the amount of coma aberration is controlled by using any conic surface as the incident surface (convex surface) of the receiving lens 7. I can't.
Therefore, when the distance between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7 is t = 0, it is necessary to increase at least one lens in order to correct coma, An increase in the number of lenses causes an increase in the cost of the receiving optical system.

On the other hand, according to the aberration theory, the amount of coma aberration can be controlled if the aperture stop portion 5 is separated from the incident surface (convex surface) of the receiving lens 7 and the distance t> 0.
In the third embodiment, the distance between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7 is t> 0, and a conic surface is used as the incident surface (convex surface) of the receiving lens 7. The coma aberration is corrected without increasing the number of lenses, and the desired imaging spot diameter p can be obtained by remaining the spherical aberration.

Hereinafter, the condition of the conic coefficient k for obtaining a desired imaging spot diameter p while correcting coma will be described.
First, the distance t between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7 needs to satisfy the equation (6).

The conic coefficient k for obtaining a desired imaging spot diameter p while correcting coma is obtained from the following equation (9) by using a distance t that satisfies the equation (6). Moreover, the vicinity value of the value obtained by Formula (9) may be sufficient.

Embodiment 4 FIG.
In the fourth embodiment, a case will be described in which the light receiving surface of the signal detector 9 is composed of a large number of pixels (pixels having light receiving sensitivity) like a two-dimensional CCD or CMOS sensor.
10 is a plan view showing a light receiving surface of a signal detector 9 of a receiving optical system according to Embodiment 4 of the present invention.
In FIG. 10, reference numeral 30 denotes a pixel having light receiving sensitivity.

Since the angle of view related to the image 1 ′ of the pointed object 1 and the angle of view related to the image 2 ′ of the pointed object 2 are different, as shown in FIG. The position of the 2 ′ imaging spot is different. In the example of FIG. 11, 31 is an imaging spot of image 1 ′, and 32 is an imaging spot of image 2 ′.
As shown in FIG. 11, when the desired imaging spot diameter is p, the imaging spot characteristic of the receiving lens 7 is that the image 2 ′ is formed at an angle of view w corresponding to the diagonal end of the signal detector 9. The spot diameter may be p.
This means that the imaging spot diameter including spherical aberration and coma aberration at the angle of view w corresponding to the diagonal end of the signal detector 9 is set to p.
However, since the shape of the imaging spot including coma is not point-symmetric but has an axial distribution, the imaging spot diameter is defined as the diameter of a circle as in the second and third embodiments. Can not do it.
Therefore, in the fourth embodiment, the imaging spot diameter p of the receiving lens 7 is defined as the rms imaging spot diameter _prms . In FIG. 11, 33 is an rms imaging spot of the image 2 ′.

式（１２）（１３）中のＡは、式（７）のＡであり、式（１２）（１３）中のＢは、式（８）のＢである。 Hereinafter, the image spot diameter p defined as rms image spot diameter p _rms, described conditions conic coefficient k to obtain the rms image spot diameter p _rms.
First, in order to be able to control the amount of coma, the distance between the aperture stop 5 and the incident surface (convex surface) of the receiving lens 7 is set to t> 0, as in the third embodiment. .
The conic coefficient k for obtaining the rms imaging spot diameter p _rms is a value obtained by substituting the following equations (11) to (13) into the following equation (10), or the vicinity of the value: Value.

A in Formulas (12) and (13) is A in Formula (7), and B in Formulas (12) and (13) is B in Formula (8).

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  1, 2 Point object, 1 ', 2' Image of point object 1, 2 Optical axis, 4 Band pass filter, 5 Aperture stop, 6 Outermost ray of light beam, 7 Receiving lens, 8 Image field Medium, 9 Signal detector, 10 Base, 11 Lens tube, 12 Covering part, 21 Long light receiving surface, 22 Area not having light receiving sensitivity, 30 Pixel having light receiving sensitivity, 31 Imaging spot of image 1 ′ , 32 Image 2 ′ imaging spot, 33 Image 2 ′ rms imaging spot.

Claims (6)

An aperture stop for reducing the diameter of the light beam emitted from the point-like object;
A receiving lens on which an incident surface on which a light beam whose diameter is reduced by the aperture stop is incident is a convex conic surface, and an output surface on which the light beam is emitted is a plane;
A signal detector that receives a light beam emitted from the emission surface of the receiving lens and detects a signal from the light beam;
The space between the output surface of the receiving lens and the signal detector is filled with a medium having a refractive index larger than air ,
The conic coefficient at the entrance surface of the receiving lens is
The focal spot of the receiving lens, the refractive index of the receiving lens, the refractive index of a medium having a refractive index greater than air, the thickness of the medium, and the imaging spot of the light beam in the signal detector corresponding to the desired signal-to-noise ratio A receiving optical system characterized by being determined by a diameter and a numerical aperture . Corresponding to the desired signal-to-noise ratio, the focal length of the receiving lens is f, the refractive index of the receiving lens is n ₂ , the refractive index of a medium having a refractive index greater than air is n ₃ , the thickness of the medium is d ₃ . When the imaging spot diameter of the light beam in the signal detector is p and the numerical aperture is NA,
The conic coefficient k at the entrance surface of the receiving lens is determined by the following equation:

The receiving optical system according to claim 1 . An aperture stop for reducing the diameter of the light beam emitted from the point-like object;
A receiving lens on which an incident surface on which a light beam whose diameter is reduced by the aperture stop is incident is a convex conic surface, and an output surface on which the light beam is emitted is a plane;
A signal detector that receives a light beam emitted from the emission surface of the receiving lens and detects a signal from the light beam;
The space between the output surface of the receiving lens and the signal detector is filled with a medium having a refractive index larger than air,
The conic coefficient at the entrance surface of the receiving lens is
The focal spot of the receiving lens, the refractive index of the receiving lens, the refractive index of a medium having a refractive index greater than air, the thickness of the medium, and the imaging spot of the light beam in the signal detector corresponding to the desired signal-to-noise ratio diameter, an aperture stop unit radius and receiving optics you characterized in that it is determined by the distance between the incident surface of the aperture stop unit and the receiving lens of the light beam narrowed by. Corresponding to the desired signal-to-noise ratio, the focal length of the receiving lens is f, the refractive index of the receiving lens is n ₂ , the refractive index of a medium having a refractive index greater than air is n ₃ , the thickness of the medium is d ₃ . When the imaging spot diameter of the light beam in the signal detector is p, the radius of the light beam focused by the aperture stop is R, and the distance between the aperture stop and the incident surface of the receiving lens is t,
Under the condition that the distance t between the aperture stop and the incident surface of the receiving lens satisfies the following equation:

The conic coefficient k at the entrance surface of the receiving lens is determined by the following equation:

The receiving optical system according to claim 3 .
An aperture stop for reducing the diameter of the light beam emitted from the point-like object;
A receiving lens on which an incident surface on which a light beam whose diameter is reduced by the aperture stop is incident is a convex conic surface, and an output surface on which the light beam is emitted is a plane;
A signal detector that receives a light beam emitted from the emission surface of the receiving lens and detects a signal from the light beam;
The space between the output surface of the receiving lens and the signal detector is filled with a medium having a refractive index larger than air,
The conic coefficient at the entrance surface of the receiving lens is
The focal length of the receiving lens, the refractive index of the receiving lens, the paraxial radius of curvature at the entrance surface of the receiving lens, the refractive index of a medium having a refractive index greater than air, the thickness of the medium, the luminous flux of the signal detector It is determined by the desired imaging spot diameter, the diagonal end of the signal detector, the radius of the light beam focused by the aperture stop, and the distance between the aperture stop and the incident surface of the receiving lens. receiving optical system that. The focal length of the receiving lens is f, the refractive index of the receiving lens is n ₂ , the paraxial radius of curvature at the entrance surface of the receiving lens is r, the refractive index of a medium having a refractive index greater than air is n ₃ , The thickness is d ₃ , the desired imaging spot diameter of the light beam in the signal detector is p _rms , the diagonal end of the signal detector is w, the radius of the light beam focused by the aperture stop is R, When the distance between the incident surfaces of the receiving lens is t,
The conic coefficient k at the entrance surface of the receiving lens is determined by the following equation:

The receiving optical system according to claim 5 .

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