Optical: systems and elements – Prism – With reflecting surface
Reexamination Certificate
2001-08-20
2002-07-30
Nguyen, Thong (Department: 2872)
Optical: systems and elements
Prism
With reflecting surface
C359S431000, C359S630000, C359S633000
Reexamination Certificate
active
06426841
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an optical unit and a zoom optical system employing the same, as well as an image pickup apparatus employing them and, more particularly, to an optical arrangement suitable for use in a video camera, a still video camera, a copying machine or the like and that employs a plurality of reflecting-type optical units each having a plurality of reflecting surfaces and performs zooming (variation of magnification) by varying the relative position between at least two optical units from among the plurality of optical units.
2. Description of Related Art
Various photographing optical systems that utilize reflecting surfaces, such as concave mirror surfaces and convex mirror surfaces, have heretofore been proposed.
FIG. 17
is a schematic view of a so-called mirror optical system composed of one concave mirror and one convex mirror.
In the mirror optical system shown in
FIG. 17
, an object light beam
104
from an object is reflected by a concave mirror
101
and travels toward an object side while being converged, and after having been reflected by a convex mirror
102
, the object light beam
104
forms an image of the object on an image plane
103
.
This mirror optical system is based on the construction of a so-called Cassegrainian reflecting telescope, and is intended to reduce the entire length of the optical system by folding, by using two opposed reflecting mirrors, and the optical path of a telephoto lens system, which is composed of refracting lenses and has an entire large length.
For similar reasons, in the field of an objective lens system that constitutes part of a telescope lens system as well, a multiplicity of types, which are arranged to reduce the entire length of an optical system by using a plurality of reflecting mirrors, have been proposed.
As is apparent from the above description, it has heretofore been proposed to provide a compact mirror optical system by efficiently folding an optical path by using reflecting mirrors in place of lenses that are commonly used in a photographing lens whose entire length is large.
However, in general, the mirror optical system, such as the Cassegrainian reflecting telescope, has the problem that part of an object ray is blocked by the convex mirror
102
. This problem is due to the fact that the convex mirror
102
is placed in the area through which the object light beam
104
passes.
To solve the problem, it has been proposed to provide a mirror optical system that employs decentered reflecting mirrors to prevent a portion of the optical system from blocking the area through which the object light beam
104
passes, i.e., to separate a principal ray
106
of the object light beam
104
from an optical axis
105
.
FIG. 18
is a schematic view of the mirror optical system disclosed in U.S. Pat. No. 3,674,334. This mirror optical system solves the above-described blocking problem by separating a principal ray
116
of an object light beam
115
from an optical axis
114
by decentering the central axis of reflecting mirrors from the optical axis
114
.
In the mirror optical system shown in
FIG. 18
, a concave mirror
111
, a convex mirror
113
and a concave mirror
112
are arranged in the order of passage of the light beam, and these mirrors
111
,
113
and
112
are reflecting mirrors that are rotationally symmetrical about the optical axis
114
, as shown by two-dot chain lines in FIG.
18
. In the shown mirror optical system, a principal ray
116
of an object light beam
115
is separated from the optical axis
114
to prevent blockage of the object light beam
115
, by using only the upper portion of the concave mirror
111
, which is above the optical axis
114
as viewed in
FIG. 18
, only the lower portion of the convex mirror
113
, which is below the optical axis
114
as viewed in
FIG. 18
, and only the lower portion of the concave mirror
112
which is below the optical axis
114
as viewed in FIG.
18
.
FIG. 19
is a schematic view of the mirror optical system disclosed in U.S. Pat. No. 5,063,586. The mirror optical system shown in
FIG. 19
solves the above-described problem by decentering the central axis of each reflecting mirror from an optical axis and separating the principal ray of an object light beam from the optical axis.
As shown in
FIG. 19
in which an axis perpendicular to an object plane
121
is defined as an optical axis
127
, a convex mirror
122
, a concave mirror
123
, a convex mirror
124
and a concave mirror
125
are arranged in the order of passage of the light beam, and the central coordinates and central axes
122
a
,
123
a
,
124
a
and
125
a
(axes which respectively connect the centers of reflecting surfaces and the centers of curvature thereof) of the reflecting surfaces of the respective mirrors
122
to
125
are decentered from the optical axis
127
. In the mirror optical system shown in
FIG. 19
, by appropriately setting the amount of decentering and the radius of curvature of each of the surfaces, each of the reflecting mirrors is prevented from blocking an object light beam
128
, so that an object image is efficiently formed on an image forming plane
126
.
In addition, U.S. Pat. Nos. 4,737,021 and 4,265,510 also disclose an arrangement for preventing the blocking problem by using part of a reflecting mirror that is rotationally symmetrical about an optical axis, or an arrangement for preventing the blocking problem by decentering the central axis of the reflecting mirror from the optical axis.
In addition, a zooming art is known that varies the image forming magnification (focal length) of a photographing optical system by relatively moving a plurality of reflecting mirrors that constitute part of the aforesaid type of mirror optical system.
For example, U.S. Pat. No. 4,812,030 discloses art for varying the magnification of the photographing optical system by relatively varying the distance between the concave mirror
101
and the convex mirror
102
and the distance between the convex mirror
102
and the image plane
103
in the construction of the Cassegrainian reflecting telescope shown in FIG.
17
.
FIG. 20
is a schematic view of another embodiment disclosed in U.S. Pat. No. 4,812,030. In the embodiment shown in
FIG. 20
, an object light beam
138
from an object is made incident on and reflected by a first concave mirror
131
, and travels toward an object side as a converging light beam and is made incident on a first convex mirror
132
. The light beam is reflected toward an image forming plane by the first convex mirror
132
and is made incident on a second convex mirror
134
as an approximately parallel light beam. The light beam is reflected by the second convex mirror
134
and is made incident on a second concave mirror
135
as a diverging light beam. The light beam is reflected by the second concave mirror
135
as a converging light beam and forms an image of the object on an image plane
137
.
In this arrangement, the distance
133
between the first concave mirror
131
and the first convex mirror
132
and the distance
136
between the second convex mirror
134
and the second concave mirror
135
are varied to perform zooming, thereby varying the focal length of the entire mirror optical system.
In the arrangement disclosed in U.S. Pat. No. 4,993,818, an image formed by the Cassegrainian reflecting telescope shown in
FIG. 17
is secondarily formed by another mirror optical system provided in a rear stage, and the magnification of the entire photographing optical system is varied by varying the image forming magnification of that secondary image forming mirror optical system.
In any of the above-described reflecting types of photographing optical systems, a large number of constituent components are needed and individual optical components need to be assembled with high accuracy to obtain the required optical performance. Particularly since the relative position accuracy of each of the reflecting mirrors is strict, it is indispensable to adjust the posit
Akiyama Takeshi
Araki Keisuke
Kimura Ken-ichi
Nanba Norihiro
Saruwatari Hiroshi
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