Patent Application
20220082805
The present disclosure relates to an optical system using a prism. The present disclosure also relates to an image projection apparatus and an imaging apparatus using such an optical system.
Patent Document 1 discloses a zooming optical system which includes an off-axial optical element located eccentrically, thereby bending the optical path inside the zooming optical system so as to have a desired shape and shortening the total length of the zooming optical system.
Patent Document 2 discloses an imaging optical system which includes a plurality of eccentric prisms. More specifically, two eccentric prisms each having a rotationally asymmetric reflection surface are located on the both sides of a stop, and the medium of the eccentric prism 10 before the stop and the medium of the eccentric prism 20 after the stop are different in optical property from each other.
[Patent Document 1] JP H10-20196 A
[Patent Document 2] JP 2003-84200 A
[Patent Document 3] JP 6390882 B
The present disclosure provides an optical system which can realize projection or imaging with a shorter focal length and a larger-sized screen using a small-sized prism. The present disclosure also provides an image projection apparatus and an imaging apparatus using such an optical system.
One aspect of the present disclosure is directed to an optical system having a reduction conjugation point on a reduction side and a magnification conjugation point on a magnification side and internally having an intermediate imaging position that is conjugated to both the reduction conjugation point and the magnification conjugation point. The reduction conjugate point has an image-forming relationship in a rectangular region having a longitudinal direction and a lateral direction. The optical system includes a first sub-optical system including an aperture stop defining a range in which a light flux can pass through the optical system and a second sub-optical system disposed on the magnification side of the first sub-optical system and including a prism made of a transparent medium. The prism has a first transmission surface located on the reduction side, a second transmission surface located on the magnification side, and at least one reflection surface located on an optical path between the first transmission surface and the second transmission surface. The aperture stop is positioned between the reduction conjugate point and the intermediate imaging position. A portion or whole of intermediate images formed at the intermediate imaging position are positioned inside the medium of the prism. A first reflection surface closest to the intermediate imaging position has a shape with a concave surface facing a direction into which a light ray incident on the first reflection surface is reflected. The second transmission surface has a shape with a convex surface facing the magnification side. In case an X-direction, a Y-direction, and a Z-direction are a longitudinal direction, a lateral direction, and a normal direction, respectively, of the rectangular region of the reduction conjugate point, when a Y cross-section is a plane including a position where a principal ray passing through the center in the X-direction is reflected by the first reflection surface, and an X cross-section is a cross-section perpendicular to the Y cross-section, a curvature shape of the first reflection surface may be set such that some of multiple principal rays passing through the reduction conjugate point intersect on the optical path between the first reflection surface and the second transmission surface as viewed in a direction perpendicular to the Y cross-section while some of multiple principal rays passing through the reduction conjugate point intersect on the optical path between the first reflection surface and the second transmission surface as viewed in a direction perpendicular to the X cross-section.
Further, an image projection apparatus according to another aspect of the present disclosure includes the above-described optical system and an image forming element that generates an image to be projected through the optical system onto a screen.
Still further, an imaging apparatus according to another aspect of the present disclosure includes the above-described optical system and an imaging element that receives an optical image formed by the optical system to convert the optical image into an electrical image signal.
In the optical system according to the present disclosure, multiple principal rays intersect on the optical path between the first reflection surface and the second transmission surface of the prism for both the Y cross-section and the X cross-section. Therefore, projection or imaging with a shorter focal length and a larger-sized screen can be realized by using a small-sized prism.
Hereinafter, embodiments are described in detail with reference to the drawings as appropriate. However, unnecessarily detailed descriptions may be omitted. For example, detailed descriptions of well-known items or redundant descriptions of substantially the same configurations may be omitted. This is to prevent the following description from being unnecessarily redundant and to facilitate understanding by those skilled in the art.
It should be noted that the applicant provides the accompanying drawings and the following description for those skilled in the art to fully understand the present disclosure, and it is not intended to limit the subject matter described in the claims thereby.
Each example of an optical system according to the present disclosure is described below. In each example, described is an example in which the optical system is used in a projector (an example of an image projection apparatus) that projects onto a screen image light of an original image SA obtained by spatially modulating incident light using an image forming element, such as liquid crystal or digital micromirror device (DMD), based on an image signal. In other words, the optical system according to the present disclosure can be used for magnifying the original image SA on the image forming element arranged on the reduction side to project the image onto the screen (not shown), which is arranged on an extension line on the magnification side. However, a projection surface is not limited to the screen. Examples of the projection surface includes walls, ceilings, floors, windows, etc. in houses, stores, or vehicles and airplanes used as means for transportation.
Further, the optical system according to the present disclosure can also be used for collecting light emitted from an object located on the extension line on the magnification side to form an optical image of the object on an imaging surface of an imaging element arranged on the reduction side.
Hereinafter, an optical system according to a first embodiment of the present disclosure will be described with reference to
An intermediate imaging position that is conjugated to both the reduction conjugate point and the magnification conjugate point is located inside the optical system 1. This intermediate imaging position is shown as a Y-direction intermediate image IMy in
The first sub-optical system includes an optical element PA and lens elements L1 to L14 in this order from the reduction side to the magnification side. The optical element PA represents different optical elements, such as a TIR (total internal reflection) prism, a prism for color separation and color synthesis, an optical filter, a flat-parallel glass plate, a crystal low-pass filter, and an infrared cut filter. The original image SA is disposed on a reduction-side end face of the optical element PA (surface 1). For the surface number, see numerical examples described later.
The optical element PA has two parallel and flat transmission surfaces (surfaces 2, 3). The lens element L1 has a positive meniscus shape with the convex surfaces facing the reduction side (surfaces 4, 5). The lens element L2 has a negative meniscus shape with the convex surfaces facing the reduction side (surfaces 6, 7). The lens element L3 has a biconvex shape (surfaces 7, 8). The lens element L4 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 8, 9). The lens elements L2 to L4 are joined to each other to form a composite lens. The lens element L5 has a biconcave shape (surfaces 10, 11). The lens element L6 has a biconvex shape (surfaces 11, 12). The lens elements L5, L6 are joined to each other to form a composite lens.
The lens element L7 has a biconvex shape (surfaces 14, 15). The lens element L8 has a negative meniscus shape with the convex surfaces surface facing the magnification side (surfaces 16, 17). The lens element L9 has a positive meniscus shape with the convex surfaces facing the magnification side (surfaces 17, 18). The lens elements L8 and L9 are joined to each other to form a composite lens. The lens element L10 has a biconvex shape (surfaces 19, 20). The lens element L11 has a biconvex shape (surfaces 21, 22). The lens element L12 has a biconcave shape (surfaces 22, 23). The lens elements L11 and L12 are joined to each other to form a composite lens. The lens element L13 has a negative meniscus shape with the convex surfaces facing the reduction side (surfaces 24, 25). The lens element L14 has a positive meniscus shape with the convex surfaces facing the magnification side (surfaces 26, 27).
The second sub-optical system includes the prism PM made of a transparent medium, such as glass, synthetic resin. The prism PM has a transmission surface A located on the reduction side, a transmission surface B located on the magnification side, and two reflection surfaces R1, R2 located on an optical path between the transmission surface A and the transmission surface B. The transmission surface A has a free-form surface shape free-form surface shape with the concave surface facing the reduction side (surface 28). The reflection surface R1 has a free-form surface shape with the concave surface facing a direction into which a light ray incident on the reflection surface R1 is reflected (surface 29). The reflection surface R2 has a planar shape (surface 30). The transmission surface B has a free-form surface shape with the convex surface facing the magnification side (surface 31).
The aperture stop ST defines a range in which a light flux can pass through the optical system 1, and is positioned between the reduction conjugate point and the intermediate imaging position described above. For example, the aperture stop ST is located between the lens element L6 and the lens element L7 (surface 13).
A portion or whole of the intermediate images formed at the intermediate imaging position, i.e., the Y-direction intermediate image IMy and the X-direction intermediate image IMx, is positioned inside the medium of the prism PM.
In case the X-direction, the Y-direction, and the Z-direction are the longitudinal direction, the lateral direction, and the normal direction, respectively, of the rectangular region of the reduction conjugate point, when a Y cross-section is a plane including a position where a principal ray passing through the center in the X-direction is reflected by the reflection surface R1, and an X cross-section is a cross-section perpendicular to the Y cross-section, the light flux passing through the first sub-optical system has different intermediate imaging positions in the Y cross-section and the X cross-section, i.e., the Y-direction intermediate image IMy and the X-direction intermediate image IMx are formed at different positions. This can reduce an influence on image quality due to disturbances, such as dust and dirt.
For clarification,
For clarification,
In the present disclosure, a curvature shape of the free-form surface of the reflection surface R1 is set such that, as shown in
Referring to the graph, the Y-direction intermediate image IMy is distributed from near the coordinates (−2.5, 0) to near the coordinates (−19.5, −14.5) obliquely with respect to the Z-direction. The X-direction intermediate image IMx is distributed from near the coordinates (0, 0) to near the coordinates (−13, −15) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side. The reflection surface R1 is distributed from near the coordinates (9, 0) to near the coordinates (0.5, −17) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side.
In the present disclosure, the reflection surface R1 may have a shape with a concave surface facing the reduction optical path side along the intermediate imaging position in the X-direction parallel to the X cross-section of the light ray passing through the center in the longitudinal direction of the above-mentioned rectangular region. As a result, image distortion on the screen SC can be suppressed.
The lens element L1 has a positive meniscus shape with the convex surfaces facing the reduction side (surfaces 4, 5). The lens element L2 has a negative meniscus shape with the convex surfaces facing the reduction side (surfaces 6, 7). The lens element L3 has a biconvex shape (surfaces 7, 8). The lens element L4 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 8, 9). The lens elements L2 to L4 are joined to each other to form a composite lens. The lens element L5 has a biconcave shape (surfaces 10, 11). The lens element L6 has a biconvex shape (surfaces 11, 12). The lens elements L5 and L6 are joined to each other to form a composite lens.
The lens element L7 has a biconvex shape (surfaces 14, 15). The lens element L8 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 16, 17). The lens element L9 has a biconvex shape (surfaces 18, 19). The lens element L10 has a biconvex shape (surfaces 20, 21). The lens element L11 has a biconcave shape (surfaces 21, 22). The lens elements L10 and L11 are joined to each other to form a composite lens. The lens element L12 has a negative meniscus shape with the convex surfaces facing the reduction side (surfaces 23, 24). The lens element L13 has a biconvex shape (surfaces 25, 26).
The prism PM has a transmission surface A located on the reduction side, a transmission surface B located on the magnification side, and two reflection surfaces R1, R2 located on an optical path between the transmission surface A and the transmission surface B. The transmission surface A has a free-form surface shape with the concave surface facing the reduction side (surface 27). The reflection surface R1 has a free-form surface shape with the concave surface facing a direction into which a light ray incident on the reflection surface R1 is reflected (surface 28). The reflection surface R2 has a planar shape (surface 29). The transmission surface B has a free-form surface shape with the convex surface facing the magnification side (surface 30).
For clarification,
For clarification,
Referring to the graph, the Y-direction intermediate image IMy is distributed from near the coordinates (−3.5, 0) to near the coordinates (−17, −10) obliquely with respect to the Z-direction. The X-direction intermediate image IMx is distributed from near the coordinates (0,0) to near the coordinates (−12, −10) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side. The reflection surface R1 is distributed from near the coordinates (5.5, 0) to near the coordinates (−2, −11) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side.
In the present disclosure, the reflection surface R1 may have a shape with a concave surface facing the reduction optical path side along the intermediate imaging position in the X-direction parallel to the X cross-section of the light ray passing through the center in the longitudinal direction of the above-mentioned rectangular region. As a result, image distortion on the screen SC can be suppressed.
The lens element L1 has a positive meniscus shape with the convex surfaces facing the reduction side (surfaces 4, 5). The lens element L2 has a negative meniscus shape with the convex surfaces facing the reduction side (surfaces 6, 7). The lens element L3 has a biconvex shape (surfaces 7, 8). The lens element L4 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 8, 9). The lens elements L2 to L4 are joined to each other to form a composite lens. The lens element L5 has a biconcave shape (surfaces 10, 11). The lens element L6 has a biconvex shape (surfaces 11, 12). The lens elements L5 and L6 are joined to each other to form a composite lens.
The lens element L7 has a biconvex shape (surfaces 14, 15). The lens element L8 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 16, 17). The lens element L9 has a positive meniscus shape with a convex surface facing the magnification side (surfaces 17, 18). The lens elements L8 and L9 are joined to each other to form a composite lens. The lens element L10 has a biconvex shape (surfaces 19, 20). The lens element L11 has a biconvex shape (surfaces 21, 22). The lens element L12 has a biconcave shape (surfaces 22, 23). The lens elements L11 and L12 are joined to each other to form a composite lens. The lens element L13 has a negative meniscus shape with the convex surfaces facing the reduction side (surfaces 24, 25). The lens element L14 has a positive meniscus shape with the convex surfaces facing the magnification side (surfaces 26, 27).
The prism PM has a transmission surface A located on the reduction side, a transmission surface B located on the magnification side, and one reflection surface R1 located on an optical path between the transmission surface A and the transmission surface B. The transmission surface A has a free-form surface shape with the concave surface facing the reduction side (surface 28). The reflection surface R1 has a free-form surface shape with the concave surface facing a direction into which a light ray incident on the reflection surface R1 is reflected (surface 29). The transmission surface B has a free-form surface shape with the convex surface facing the magnification side (surface 30).
For clarification,
For clarification,
Referring to the graph, the Y-direction intermediate image IMy is distributed from near the coordinates (−2, 0) to near the coordinates (−19, −14.5) obliquely with respect to the Z-direction. The X-direction intermediate image IMx is distributed from near the coordinates (0, 0) to near the coordinates (−12.5, −15) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side. The reflection surface R1 is distributed from near the coordinates (9,0) to near the coordinates (1, −17) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side.
In the present disclosure, the reflection surface R1 may have a shape with a concave surface facing the reduction optical path side along the intermediate imaging position in the X-direction parallel to the X cross-section of the light ray passing through the center in the longitudinal direction of the above-mentioned rectangular region. As a result, image distortion on the screen SC can be suppressed.
The lens element L1 has a biconvex shape (surfaces 2, 3). The lens element L2 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 4, 5). The lens element L3 has a negative meniscus shape with the convex surfaces facing the magnification side (surfaces 6, 7).
Similarly to the prism PM, the prism PF is made of a transparent medium such as glass, synthetic resin. The prism PF has a transmission surface P located on the reduction side, a transmission surface Q located on the magnification side, and three reflection surfaces K1, K2, K3 located on an optical path between the transmission surface P and the transmission surface Q. The transmission surface P has a free-form surface shape with the concave surface facing the reduction side (surface 9). The reflection surface K1 has a free-form surface shape with the concave surface facing the reduction side and the magnification side (surface 10). The reflection surface K2 has a free-form surface shape with the convex surface facing the reduction side and the magnification side (surface 11). The reflection surface K3 has a free-form surface shape with the concave surface facing the reduction side and the magnification side (surface 12). The transmission surface Q has a free-form surface shape with the convex surface facing the reduction side (surface 13).
The prism PM has a transmission surface A located on the reduction side, a transmission surface B located on the magnification side, and two reflection surfaces R1, R2 located on an optical path between the transmission surface A and the transmission surface B. The transmission surface A has a free-form surface shape with the convex surface facing the reduction side (surface 14). The reflection surface R1 has a free-form surface shape with the concave surface facing the reduction side and the magnification side (surface 15). The reflection surface R2 has a free-form surface shape with the convex surface facing in a direction into which a light ray incident on the reflection surface R1 is reflected (surface 16). The transmission surface B has a free-form surface shape with the convex surface facing the magnification side (surface 17).
The aperture stop ST defines the range in which a light flux can pass through the optical system 1, and is positioned between the reduction conjugate point and the intermediate imaging position described above. For example, the aperture stop ST is located between the lens element L3 and the transmission surface P of the prism PM (surface 8).
For clarification,
For clarification,
Referring to the graph, the Y-direction intermediate image IMy is distributed from near the coordinates (−1, 0) to near the coordinates (12, −5.7) obliquely with respect to the Z-direction. The X-direction intermediate image IMx is distributed from near the coordinates (0, 0) to near the coordinates (7.5, −6) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side. The reflection surface R1 is distributed from near the coordinates (−4.5, −0.5) to near the coordinates (−0.8, −6.8) obliquely with respect to the Z-direction in a concave shape facing the reduction optical path side.
In the present disclosure, the reflection surface R1 may have a shape with a concave surface facing the reduction optical path side along the intermediate imaging position in the X-direction parallel to the X cross-section of the light ray passing through the center in the longitudinal direction of the above-mentioned rectangular region. As a result, image distortion on the screen SC can be suppressed. In the optical system 1 according to the example 4, the prism PF and the prism PM made of media having different refractive indexes and Abbe numbers are more effective for correction of the chromatic aberration of magnification than the prisms made of the same medium.
Next, conditions which the optical system according to the examples 1 to 4 can satisfy are described below. Although a plurality of the conditions are defined for the optical system according to each of the examples, all of these plurality of conditions may be satisfied, or the individual conditions may be satisfied to obtain the corresponding effects.
The optical system according to this embodiment is the optical system 1 having a reduction conjugation point on the reduction side and a magnification conjugation point on the magnification side and internally having an intermediate imaging position that is conjugated to both the reduction conjugation point and the magnification conjugation point,
wherein the reduction conjugate point has an image-forming relationship in a rectangular region having a longitudinal direction and a lateral direction,
wherein the optical system includes the first sub-optical system including the aperture stop ST defining a range in which a light flux can pass through the optical system 1 and the second sub-optical system disposed on the magnification side of the first sub-optical system and including the prism PM made of a transparent medium,
wherein the prism PM has the transmission surface A located on the reduction side, the transmission surface B located on the magnification side, and the at least one reflection surface R1 located on an Optical path between the transmission surface A and the transmission surface B,
wherein the aperture stop ST is positioned between the reduction conjugate point and the intermediate imaging position,
wherein a portion or whole of intermediate images IMx, IMy formed at the intermediate imaging position are positioned inside the medium of the prism PM,
wherein the reflection surface R1 closest to the intermediate imaging position has a shape with a concave surface facing a direction into which a light ray incident on the reflection surface R1 is reflected,
wherein the transmission surface B has a shape with a convex surface facing the magnification side, and
wherein in case an X-direction, a Y-direction, and a Z-direction are a longitudinal direction, a lateral direction, and a normal direction, respectively, of the rectangular region of the reduction conjugate point, when a Y cross-section is a plane including a position where a principal ray passing through the center in the X-direction is reflected by the reflection surface R1, and an X cross-section is a cross-section perpendicular to the Y cross-section, a curvature shape of the reflection surface R1 may be set such that some of multiple principal rays passing through the reduction conjugate point intersect on the optical path between the reflection surface R1 and the transmission surface B as viewed in a direction perpendicular to the Y cross-section while some of multiple principal rays passing through the reduction conjugate point intersect on the optical path between the reflection surface R1 and the transmission surface B as viewed in a direction perpendicular to the X cross-section.
With this configuration, multiple principal rays intersect on the optical path between the reflection surface R1 and the transmission surface B of the prism for both the Y cross-section and the X cross-section. Therefore, the second sub-optical system can be miniaturized, and projection or imaging with a shorter focal length and a larger-sized screen can be realized by using a small-sized prism.
In the optical system according to this embodiment, the reflection surface R1 may have a shape with a concave surface facing the reduction optical path side along the intermediate imaging position in the X-direction parallel to the X cross-section of the light ray passing through the center in the longitudinal direction of the rectangular region.
With this configuration, image distortion on the screen SC can be suppressed.
In the optical system according to this embodiment, the light flux passing through the first sub-optical system may include different intermediate imaging positions in the Y cross-section and the X cross-section.
With this configuration, the imaging magnification ratios can independently be set in the X-direction and the Y-direction, with an increased degree of freedom in design.
In the Y-direction, a length ΔY1 at the reduction conjugate point, a length ΔY2 at the intermediate imaging position in the Y-direction, and a length ΔY3 at the magnification conjugate point are imaged at predetermined magnification ratios, respectively. In this case, the imaging magnification ratio MY at the intermediate imaging position in the Y-direction parallel to the Y cross-section with respect to the reduction conjugate point and the Y-direction imaging magnification ratio MMY at the magnification conjugate point with respect to the reduction conjugate point are given by the following equations:
MY=|ΔY2/ΔY1|
MMY=|ΔY3/ΔY1|
Similarly, in the X-direction, a length ΔX1 at the reduction conjugate point, a length ΔX2 at the intermediate imaging position in the X-direction, and a length ΔX3 at the magnification conjugate point are imaged at predetermined magnification ratios, respectively. In this case, the imaging magnification ratio MX at the intermediate imaging position in the X-direction parallel to the X cross-section with respect to the reduction conjugate point and the X-direction imaging magnification ratio MMX at the magnification conjugate point with respect to the reduction conjugate point are given by the following equations:
MX=|ΔX2/ΔX1|
MMX=|ΔX3/ΔX1|
The optical system according to this embodiment may satisfy the following condition (1a) or condition (1b):
0<|MX|<10 (1a)
0<|MY|<10 (1b)
where MX is the imaging magnification ratio at the intermediate imaging position in the X-direction parallel to the X cross-section with respect to the reduction conjugate point, and MY is the imaging magnification ratio at the intermediate imaging position in the Y-direction parallel to the Y cross-section with respect to the reduction conjugate point.
With this configuration, the intermediate imaging position can appropriately be set, and image distortion on the screen SC can be suppressed while maintaining the second sub-optical system in small size. Additionally, in the range described above, a difference between the X-direction imaging magnification ratio and the Y-direction imaging magnification ratio on the screen SC can be made as small as possible. If exceeding the upper limit of the condition (1a) or the condition (1b), the intermediate image formed in the second sub-optical system becomes larger, which makes it difficult to maintain the small size. It is preferable that the imaging magnification ratios MX, MY at the intermediate imaging position are set to gradually decrease from the normalized height Y=0 toward Y=1 at the reduction conjugate point. As a result, the curvature of field at the intermediate imaging position can be set on the under side (the reduction optical path side), and the curvature of field on the screen SC can be suppressed within a favorable range.
Furthermore, the effect described above can be enhanced by satisfying the following condition (1c) or (1d):
0.5<|MX|<7.5 (1c)
0.5<|MY|<7.5 (1d)
Furthermore, the effect described above can be enhanced by satisfying the following condition (1e) or (1f):
0.6<|MX|<5.0 (1e)
0.6<|MY|<5.0 (1f)
The optical system according to this embodiment may satisfy the following condition (2):
|MX|>|MY| (2)
With this configuration, a difference between the X-direction imaging magnification ratio and the Y-direction imaging magnification ratio on the screen SC can be made as small as possible. If the condition (2) is not satisfied, a difference between the X-direction imaging magnification ratio and the Y-direction imaging magnification ratio on the screen SC may be produced, which makes it difficult to maintain appropriate optical performance.
In the optical system according to this embodiment, the intermediate imaging position in the X-direction may exist between the intermediate imaging position in the Y-direction and the reflection surface R1.
With this configuration, a difference between the X-direction imaging magnification ratio and the Y-direction imaging magnification ratio on the screen SC can be made as small as possible.
The optical system according to this embodiment may satisfy the following condition (3):
Σ(|OPLY|−|OPLX|)>0 (3)
where OPLX is an optical path length between the intermediate imaging position in the X-direction and the reflection surface R1, and OPLY is an optical path length between the intermediate imaging position in the Y-direction and the reflection surface R1, and Σ(|OPLY|−|OPLX|) is a total value obtained by adding the difference between the absolute value of the optical path length OPLX and the absolute value of the optical path length OPLY for three principal rays passing through the normalized heights Y=0.0, 0.5, 1.0 at the reduction conjugate point.
With this configuration, a difference between the X-direction imaging magnification ratio and the Y-direction imaging magnification ratio on the screen SC can be made as small as possible. If falling below the lower limit of the condition (3), the Y-direction imaging magnification ratio becomes smaller than the X-direction imaging magnification ratio on the screen SC, which makes it difficult to appropriately reproduce the original image SA.
Furthermore, the effect described above can be enhanced by satisfying the following condition (3a):
Σ(|OPLY|−|OPLX|)>2.5 (3a)
Furthermore, the effect described above can be enhanced by satisfying the following condition (3b):
Σ(|OPLY|−|OPLX|)>5.0 (3b)
The optical system according to this embodiment may satisfy the following condition (4):
|2×(MMX−MMY)/(MMX+MMY)|<0.30 (4)
where MMX is the X-direction imaging magnification ratio at the magnification conjugate point with respect to the reduction conjugate point, and MMY is the Y-direction imaging magnification ratio at the magnification conjugate point with respect to the reduction conjugate point.
With this configuration, image distortion on the screen SC can be suppressed, and a difference between the X-direction imaging magnification ratio and the Y-direction imaging magnification ratio can be made as small as possible. If exceeding the upper limit of the condition (4), the Y-direction imaging magnification ratio becomes different from the X-direction imaging magnification ratio on the screen SC, which makes it difficult to appropriately reproduce the original image SA. The condition (4) defines a range in which the original image SA can be appropriately reproduced on the screen SC.
Furthermore, the effect described above can be enhanced by satisfying the following condition (4a):
|2×(MMX−MMY)/(MMX+MMY)|<0.15 (4a)
Furthermore, the effect described above can be enhanced by satisfying the following condition (4b):
|2×(MMX−MMY)/(MMX+MMY)|<0.08 (4b)
The optical system according to this embodiment may satisfy the following condition (5):
|θi|<50 (5)
where θi is an incident angle (unit: degrees) relative to the normal of the transmission surface B at the position where a principal ray is incident on the transmission surface B when the principal ray passes through the transmission surface B of the medium.
With this configuration, the light reflected by the transmitting surface B can be suppressed when passing through the transmitting surface B, and a loss of the transmitted light can be reduced, so that a decrease in amount of light of a projected image can be suppressed.
In the optical system according to this embodiment, the transmission surface B may have the maximum effective area among the transmission surface A, the transmission surface B, and the at least one reflection surface R1.
With this configuration, a uniform amount of light can be achieved in the projected image.
In the optical system according to this embodiment, the aperture stop ST may be positioned between the reduction conjugate point and the transmission surface A.
With this configuration, the prism PM can be miniaturized.
In the optical system according to this embodiment, all of the multiple principal rays passing through the reduction conjugate point may intersect on the optical path between the reflection surface R1 and the transmission surface B.
With this configuration, the second sub optical system can be miniaturized and projection or imaging with a shorter focal length and a larger-sized screen can be realized by using a small-sized prism.
In the optical system according to this embodiment, either an entrance pupil or an exit pupil corresponding to the aperture stop may be positioned in the prism. The entrance pupil is an image of the aperture stop viewed from the reduction side. The exit pupil is an image of the aperture stop viewed from the magnification side.
With this configuration, the second sub optical system can be miniaturized and projection or imaging with a shorter focal length and a larger-sized screen can be realized by using a small-sized prism.
In the optical system according to this embodiment, the intermediate imaging position may be positioned away from the reflection surface R1 toward the reduction side.
With this configuration, image distortion on the screen SC can be suppressed.
The prism PM is provided with, for example, an end surface PMa and an inside corner PMb each serving as attachment references. On the other hand, the lens barrel 50 is provided with an end surface 50a and an outside corner 50b each corresponding to the shapes of the end surface PMa and the inside corner PMb. During attachment, the end surface PMa and the end surface 50a are matched and the inside corner PMb and the outside corner 50b are matched, so that the prism PM can be highly accurately and stably fixed to the lens barrel 50.
The optical system according to this embodiment may have a stepped structure formed on an outer circumferential portion of the prism PM.
With this configuration, the prism can be highly accurately and stably attached to an outer housing.
Regarding the optical system according to this embodiment, the optical system may be an imaging optical system.
With this configuration, the second sub-optical system can be miniaturized, and projection or imaging with a shorter focal length and a larger-sized screen can be realized by using a small-sized prism.
Hereinafter, numerical examples of the optical system according to examples 1 to 4 are described. In each of the numerical examples, in the table, the unit of length is all “mm”, and the unit of angle of view is all “°” (degree). Further, in each of the numerical examples, radius of curvature, surface interval, Nd (refractive index for d line), νd (Abbe number for d line), N550 (refractive index at a wavelength of 550 nm), eccentricity data (displacements X, Y, Z of a prism surface with respect to the previous surface and normal directions α, β, γ of the prism surface with respect to the previous surface in the optical system) are listed. The term “variable” in the surface interval means that it can be varied depending on the size of image (e.g., 100″(inch), 80″, 60″, etc.) on the magnification conjugate point. Furthermore, in each of the numerical examples, the aspherical (ASP) shape is defined by the following formula, where for the aspherical coefficient, only non-zero coefficients are shown other than conic constant.
where, Z is a sag height of a surface as measured in parallel to z-axis, r is a distance in the radial direction (=√(x2+y2)), c is a vertex curvature, k is a conic constant, and A to H are 4th to 18th order aspherical coefficients.
A free-form surface (FFS) shape is defined by the following formulas using a local Cartesian coordinate system with the vertex thereof as origin point.
where, Z is a sag height of a surface as measured in parallel to z-axis, r is a distance in the radial direction (=√(x2+y2)), c is a vertex curvature, k is a conic constant, and Cj is a coefficient of a monomial Xmyn.
Further, in the following data table, member of ith-order of x and jth-order of y, showing a free-form surface coefficient in the polynomial formula, is expressed by the shorthand notation “X**i*Y**i”. For example, a notation “X**2*Y” shows a free-form surface coefficient of a member of 2nd-order of x and 1st-order of y in the polynomial formula.
Regarding the optical system of numerical example 1 (corresponding to example 1), Table 1 shows lens data, Table 2 shows aspherical surface shape data of the lenses, and Table 3 shows free-form surface shape data of the prism.
Regarding the optical system of numerical example 2 (corresponding to example 2), Table 4 shows lens data, Table 5 shows aspherical surface shape data of the lenses, and Table 6 shows free-form surface shape data of the prism.
Regarding the optical system of numerical example 3 (corresponding to example 3), Table 7 shows lens data, Table 8 shows aspherical surface shape data of the lenses, and Table 9 shows free-form surface shape data of the prism.
Regarding the optical system of numerical example 4 (corresponding to example 4), Table 10 shows lens data, and Table 11 shows free-form surface shape data of the prism. Only in Example 4 the lens data show absolute (global) coordinates based on the first surface.
Tables 12 to 15 below show the corresponding values of the respective conditional expressions (1) to (4) in the respective numerical examples 1 to 4.
Table 16 below shows the corresponding values of the conditional expression (5) in the respective numerical examples 1 to 4.
Hereinafter, a second embodiment of the present disclosure is described with reference to
The image projection apparatus 100 described above can become larger-sized and realize projection with a shorter focal length and a larger-sized screen.
Hereinafter, a third embodiment of the present disclosure is described with reference to
The imaging apparatus 200 described above can become larger-sized and realize imaging with a shorter focal length and a larger-sized screen.
As described above, the embodiments have been described to disclose the technology in the present disclosure. To that end, the accompanying drawings and detailed description are provided.
Therefore, among the components described in the accompanying drawings and the detailed description, not only the components that are essential for solving the problem, but also the components that are not essential for solving the problem may also be included in order to exemplify the above-described technology. Therefore, it should not be directly appreciated that the above non-essential components are essential based on the fact that the non-essential components are described in the accompanying drawings and the detailed description.
Further, the above-described embodiments have been described to exemplify the technology in the present disclosure. Thus, various modification, substitution, addition, omission and so on can be made within the scope of the claims or equivalents thereof.
The present disclosure can be applied to image projection apparatuses such as projectors and head-up displays, and imaging apparatuses such as digital still cameras, digital video cameras, surveillance cameras in surveillance systems, web cameras, and onboard cameras. In particular, the present disclosure can be applied to optical systems that require a high image quality, such as projectors, digital still camera systems, and digital video camera systems.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2019-100454 | May 2019 | JP | national |
This application is a continuation of International Patent Application No. PCT/JP2019/049166, filed on Dec. 16, 2019, which claims the benefit of Japanese Patent Application No. 2019-100454, filed on May 29, 2019, the contents all of which are incorporated herein by reference.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2019/049166 | Dec 2019 | US |
| Child | 17511799 | US |
