JP7280561B2 - Eyepiece optical system and imaging device - Google Patents
Eyepiece optical system and imaging device Download PDFInfo
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Description
本発明は、接眼光学系及び撮像装置に関する。 The present invention relates to an eyepiece optical system and an imaging device.
従来、高い結像性能を有する接眼光学系が提案されている(例えば、特許文献1参照)。しかしながら、特許文献1は、さらなる光学性能の向上が要望されているという課題があった。 Conventionally, an eyepiece optical system having high imaging performance has been proposed (see, for example, Patent Document 1). However, Patent Document 1 has a problem that further improvement in optical performance is demanded.
本発明の第一の態様に係る接眼光学系は、観察物体側から順に、正の屈折力を有する単レンズである第1レンズと、観察物体側に凹面を向けたメニスカスレンズ形状の負の屈折力を有する単レンズである第2レンズと、正の屈折力を有する単レンズである第3レンズと、観察物体側に凹面を向けたメニスカスレンズ形状の正の屈折力を有する単レンズである第4レンズとの実質的に4個のレンズからなり、次式の条件を満足する。
1.38 < fe/f1 < 1.65
1.600 < nd1 < 1.800
但し、
fe:当該接眼光学系の全系の焦点距離
f1:第1レンズの焦点距離
nd1:第1レンズの媒質のd線に対する屈折率
An eyepiece optical system according to a first aspect of the present invention comprises, in order from the observation object side, a first lens which is a single lens having a positive refractive power, and a meniscus-shaped negative refractive lens with a concave surface facing the observation object side. The second lens is a single lens having power, the third lens is a single lens having positive refractive power, and the third lens is a meniscus lens having a concave surface facing the observation object side and having positive refractive power. It consists of substantially four lenses and satisfies the following condition.
1.38<fe/f1<1.65
1.600 < nd1 < 1.800
however,
fe: focal length of the entire eyepiece optical system f1: focal length of the first lens nd1: refractive index of the medium of the first lens for the d-line
以下、好ましい実施形態について図面を参照して説明する。図1に示すように、本実施形態に係る接眼光学系ELは、観察物体側(単に「物体」とも呼ぶ)から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有している。 Preferred embodiments are described below with reference to the drawings. As shown in FIG. 1, the eyepiece optical system EL according to the present embodiment has a first lens component G1 having a positive refractive power and a negative refractive power in order from the observation object side (simply referred to as "object"). a second lens component G2 having a positive refractive power, a third lens component G3 having a positive refractive power, and a fourth lens component G4 having a positive refractive power.
なお、「レンズ成分」とは単レンズ又は接合レンズのことをいう。また、「レンズ要素」とは単レンズ又は接合レンズを構成する各々のレンズのことをいう。また、「基準視度」とは、視度が-1[1/m]のときをいう。ここで、単位[1/m]について、視度X[1/m]とは、接眼光学系ELによる像がアイポイントから光軸上に1/X[m(メートル)]の位置にできる状態のことを示す(符号は像が接眼光学系ELより観察者側(アイポイント側)にできたときを正とする)。 In addition, a "lens component" means a single lens or a cemented lens. A "lens element" refers to each lens that constitutes a single lens or a cemented lens. In addition, the “reference diopter” refers to the diopter of −1 [1/m]. Here, regarding the unit [1/m], the diopter X [1/m] is a state in which an image formed by the eyepiece optical system EL can be positioned 1/X [m (meters)] on the optical axis from the eye point. (The symbol is positive when the image is formed on the observer side (eyepoint side) from the ocular optical system EL).
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(1)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (1).
1.38 < fe/f1 < 3.00 (1)
但し、
fe:当該接眼光学系ELの全系の焦点距離
f1:第1レンズ成分G1の焦点距離
1.38<fe/f1<3.00 (1)
however,
fe: focal length of the entire eyepiece optical system EL f1: focal length of the first lens component G1
条件式(1)は、球面収差、コマ収差を良好に保ちつつ、接眼光学系ELの全体の屈折力を強くするために、最も観察物体側の第1レンズ成分G1の屈折力を規定するものである。上記の、観察物体側から正、負、正、正の屈折力配置の接眼光学系ELでは、最も観察物体側の第1レンズ成分G1は、球面収差、コマ収差に最も影響を与えない。第1レンズ成分G1は像面湾曲の悪化に大きく影響するが、第1レンズ成分G1の正の屈折力で発生した像面湾曲は、第2レンズ成分G2の負の屈折力で補正することが可能である。そこで、球面収差、コマ収差を良好に保ちながら、接眼光学系ELの観察倍率を大きくするには、最も観察物体側の第1レンズ成分G1に強い正の屈折力を持たせることが必要となる。この条件式(1)の下限値を下回ると、最も観察物体側の第1レンズ成分G1の正の屈折力が弱くなり、接眼光学系EL全体の屈折力が弱くなり、観察倍率を大きくすることが困難となるため好ましくない。なお、この条件式(1)の効果を確実なものとするために、条件式(1)の下限値を1.45、更に1.48、更に1.50とすることがより望ましい。また、条件式(1)の上限値を上回ると、最も観察物体側の第1レンズ成分G1の正の屈折力が強くなり、第1レンズ成分G1で発生する像面湾曲が大きくなり、第2レンズ成分G2で像面湾曲が補正しきれなくなるため好ましくない。なお、この条件式(1)の効果を確実なものとするために、条件式(1)の上限値を2.00、更に1.65とすることがより望ましい。 Conditional expression (1) defines the refractive power of the first lens component G1 closest to the observation object side in order to increase the overall refractive power of the eyepiece optical system EL while maintaining good spherical aberration and coma. is. In the above-described eyepiece optical system EL having a positive, negative, positive, positive refractive power arrangement from the observation object side, the first lens component G1 closest to the observation object side has the least effect on spherical aberration and coma. The first lens component G1 greatly affects the deterioration of the curvature of field, but the curvature of field caused by the positive refractive power of the first lens component G1 can be corrected by the negative refractive power of the second lens component G2. It is possible. Therefore, in order to increase the observation magnification of the eyepiece optical system EL while maintaining good spherical aberration and coma aberration, it is necessary to give the first lens component G1 closest to the observation object side a strong positive refractive power. . If the lower limit of conditional expression (1) is not reached, the positive refractive power of the first lens component G1 closest to the observation object weakens, and the refractive power of the entire eyepiece optical system EL weakens, increasing the observation magnification. It is not preferable because it becomes difficult to In order to ensure the effect of conditional expression (1), it is more desirable to set the lower limit of conditional expression (1) to 1.45, more preferably 1.48, more preferably 1.50. When the upper limit of conditional expression (1) is exceeded, the positive refractive power of the first lens component G1 closest to the observation object increases, the curvature of field generated in the first lens component G1 increases, and the second lens component G1 increases. This is not preferable because the field curvature cannot be corrected by the lens component G2. In order to ensure the effect of conditional expression (1), it is more desirable to set the upper limit of conditional expression (1) to 2.00, more preferably 1.65.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(2)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (2).
0.48 < fe/f12 < 3.00 (2)
但し、
fe:当該接眼光学系ELの全系の焦点距離
f12:第1レンズ成分G1と第2レンズ成分G2との合成焦点距離
0.48<fe/f12<3.00 (2)
however,
fe: focal length of the entire eyepiece optical system EL f12: combined focal length of the first lens component G1 and the second lens component G2
条件式(2)は、観察倍率を大きくするとともに、像面湾曲を良好に補正するため、第1レンズ成分G1と第2レンズ成分G2の合成屈折力を規定するものである。第1レンズ成分G1の屈折力と第2レンズ成分G2の屈折力は、像面湾曲の補正、発生に大きく影響を与える。像面湾曲を発生させないためには、第1レンズ成分G1と第2レンズ成分G2の合成屈折力を弱くすることが望ましい。しかし一方で、第1レンズ成分G1と第2レンズ成分G2の合成屈折力を弱くすると、全接眼光学系ELの屈折力が弱くなり、観察倍率を大きくすることが困難となる。また、第1レンズ成分G1と第2レンズ成分G2の合成屈折力が弱く、観察倍率を無理に大きくしようとすると、第3レンズ成分G3、第4レンズ成分G4の屈折力が強くなり、球面収差、コマ収差を悪化させる。この条件式(2)の下限値を下回ると、第1レンズ成分G1と第2レンズ成分G2の合成屈折力が弱くなり、観察倍率を大きくすることができないため好ましくない。また、条件式(2)の下限値を下回った状態で観察倍率を大きくすると、球面収差、コマ収差が悪化するため好ましくない。なお、この条件式(2)の効果を確実なものとするために、条件式(2)の下限値を0.48、更に0.50、更に0.55とすることがより望ましい。また、条件式(2)の上限値を上回ると、第1レンズ成分G1と第2レンズ成分G2の合成屈折力が強くなり、像面湾曲が発生するため好ましくない。なお、この条件式(2)の効果を確実なものとするために、条件式(2)の上限値を1.00、更に0.70とすることがより望ましい。 Conditional expression (2) prescribes the combined refractive power of the first lens component G1 and the second lens component G2 in order to increase the observation magnification and satisfactorily correct the curvature of field. The refractive power of the first lens component G1 and the refractive power of the second lens component G2 greatly affect the correction and generation of field curvature. In order to prevent field curvature, it is desirable to weaken the combined refractive power of the first lens component G1 and the second lens component G2. On the other hand, however, if the composite refractive power of the first lens component G1 and the second lens component G2 is weakened, the refractive power of the entire eyepiece optical system EL is weakened, making it difficult to increase the observation magnification. In addition, the combined refractive power of the first lens component G1 and the second lens component G2 is weak, and if the observation magnification is forcibly increased, the refractive power of the third lens component G3 and the fourth lens component G4 increases, resulting in spherical aberration. , worsens coma. If the lower limit of conditional expression (2) is not reached, the composite refractive power of the first lens component G1 and the second lens component G2 becomes weak, and the observation magnification cannot be increased, which is not preferable. Further, if the observation magnification is increased when the lower limit of conditional expression (2) is not reached, spherical aberration and coma aberration become worse, which is not preferable. In order to ensure the effect of conditional expression (2), it is more desirable to set the lower limit of conditional expression (2) to 0.48, more preferably 0.50, more preferably 0.55. Further, if the upper limit of conditional expression (2) is exceeded, the composite refractive power of the first lens component G1 and the second lens component G2 will become strong, and field curvature will occur, which is not preferable. In order to ensure the effect of conditional expression (2), it is more desirable to set the upper limit of conditional expression (2) to 1.00, more preferably 0.70.
また、本実施形態に係る接眼光学系ELにおいて、最もアイポイント側のレンズのアイポイント側のレンズ面を、アイポイント側に凸の面形状にすると、観察物体の中心付近の光線は、最もアイポイント側のレンズのアイポイント側のレンズ面からの射出角が小さくなり、球面収差の発生量を抑えることができる。一方で、画面周辺部の光線の射出角を、大きくすることができ、コマ収差の補正が可能となる。 Further, in the eyepiece optical system EL according to this embodiment, if the lens surface on the eye point side of the lens closest to the eye point is made convex toward the eye point, the rays near the center of the observed object will be the closest to the eye point. The angle of emergence from the lens surface on the eye point side of the lens on the point side becomes small, and the amount of spherical aberration generated can be suppressed. On the other hand, it is possible to increase the angle of emergence of light rays in the peripheral portion of the screen, making it possible to correct coma aberration.
また、本実施形態に係る接眼光学系ELにおいて、第2レンズ成分G2を構成するレンズ要素の少なくとも1つは、以下に示す条件式(3)を満足することが望ましい。 Further, in the eyepiece optical system EL according to this embodiment, it is desirable that at least one of the lens elements forming the second lens component G2 satisfies the following conditional expression (3).
15.0 < νd2 < 35.0 (3)
但し、
νd2:第2レンズ成分G2を構成するレンズ要素の内、最も負の屈折力が強いレンズ要素の媒質のd線に対するアッベ数
15.0 < vd2 < 35.0 (3)
however,
νd2: Abbe number for the d-line of the medium of the lens element having the strongest negative refractive power among the lens elements that make up the second lens component G2
条件式(3)は、倍率色収差を良好に補正するため、第2レンズ成分G2を構成するレンズ要素の内、最も負の屈折力が強いレンズ要素のアッベ数を規定するものである。特に、上述した条件式(2)を満たすように、第1レンズ成分G1と第2レンズ成分G2の合成屈折力を、強い正の屈折力を持たせると、第2レンズ成分G2の負の屈折力は小さくなる。そこで、第2レンズ成分G2の内、最も負の屈折力が強いレンズ要素の分散を大きくすることで、弱い第2レンズ成分G2の負の屈折力でも、良好に倍率色収差を補正できるようにした。この条件式(3)の下限値を下回ると、倍率色収差の過補正が起き、倍率色収差が悪化するため好ましくない。なお、この条件式(3)の効果を確実なものとするために、条件式(3)の下限値を20、更に30とすることがより望ましい。また、条件式(3)の上限値を上回ると、倍率色収差が補正しきれないため好ましくない。なお、この条件式(3)の効果を確実なものとするために、条件式(3)の上限値を22とすることが望ましい。 Conditional expression (3) defines the Abbe number of the lens element having the strongest negative refractive power among the lens elements forming the second lens component G2 in order to satisfactorily correct the chromatic aberration of magnification. In particular, if the composite refractive power of the first lens component G1 and the second lens component G2 is given a strong positive refractive power so as to satisfy the conditional expression (2) described above, then the negative refractive power of the second lens component G2 can be obtained. power becomes smaller. Therefore, by increasing the dispersion of the lens element with the strongest negative refractive power among the second lens components G2, it is possible to satisfactorily correct the chromatic aberration of magnification even with the weak negative refractive power of the second lens component G2. . If the lower limit of conditional expression (3) is not reached, the chromatic aberration of magnification will be overcorrected and the chromatic aberration of magnification will deteriorate, which is not preferable. In order to ensure the effect of conditional expression (3), it is more desirable to set the lower limit of conditional expression (3) to 20, more preferably 30. Moreover, if the upper limit of conditional expression (3) is exceeded, the chromatic aberration of magnification cannot be corrected, which is not preferable. In order to ensure the effect of conditional expression (3), it is desirable to set the upper limit of conditional expression (3) to 22.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(4)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (4).
0.01 < fe/f4 < 0.33 (4)
但し、
fe:当該接眼光学系ELの全系の焦点距離
f4:第4レンズ成分G4の焦点距離
0.01<fe/f4<0.33 (4)
however,
fe: focal length of the entire eyepiece optical system EL f4: focal length of the fourth lens component G4
条件式(4)は球面収差、コマ収差を良好に補正するため、最もアイポイント側のレンズの屈折力を規定するものである。最もアイポイント側の第4レンズ成分G4は、球面収差とコマ収差への影響が最も大きい。そのため、条件式(4)の上限値を上回ると、第4レンズ成分G4の持つ正の屈折力が強くなり、球面収差とコマ収差が大きく悪化するため好ましくない。なお、この条件式(4)の効果を確実なものとするために、条件式(4)の上限値を0.30、更に0.25、更に0.239とすることがより望ましい。また、条件式(4)の下限値を下回ると、接眼光学系ELの全体の屈折力(パワー)を強くすることが難しくなるため、観察倍率の高倍率化が不可能となるため好ましくない。仮に、第4レンズ成分G4の屈折力が条件式(4)の下限値を下回り、観察倍率を高倍率化したとすると、第1レンズ成分G1及び第3レンズ成分G3の正の屈折力が極端に強くなる、または、第2レンズ成分G2の負の屈折力が弱くなることにより、像面湾曲の補正が難しくなる。なお、この条件式(4)の効果を確実なものとするために、条件式(4)の下限値を0.10、更に0.15とすることがより望ましい。 Conditional expression (4) defines the refracting power of the lens closest to the eye point in order to satisfactorily correct spherical aberration and coma. The fourth lens component G4 closest to the eye point has the greatest influence on spherical aberration and coma. Therefore, if the upper limit of conditional expression (4) is exceeded, the positive refracting power of the fourth lens component G4 becomes strong, and this greatly deteriorates spherical aberration and coma, which is not preferable. In order to ensure the effect of conditional expression (4), it is more desirable to set the upper limit of conditional expression (4) to 0.30, more preferably 0.25, and more preferably 0.239. If the lower limit of conditional expression (4) is not reached, it becomes difficult to increase the refractive power (power) of the eyepiece optical system EL as a whole, making it impossible to increase the observation magnification, which is not preferable. If the refractive power of the fourth lens component G4 falls below the lower limit of conditional expression (4) and the observation magnification is increased, the positive refractive power of the first lens component G1 and the third lens component G3 becomes extreme. or the negative refractive power of the second lens component G2 becomes weaker, it becomes difficult to correct the curvature of field. In order to ensure the effect of conditional expression (4), it is more desirable to set the lower limit of conditional expression (4) to 0.10, more preferably 0.15.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(5)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (5).
-0.30<(G2R2-G3R1)/(G2R2+G3R1)<0.50 (5)
但し、
G2R2:第2レンズ成分G2の最もアイポイント側のレンズ面の曲率半径
G3R1:第3レンズ成分G3の最も観察物体側のレンズ面の曲率半径
-0.30<(G2R2-G3R1)/(G2R2+G3R1)<0.50 (5)
however,
G2R2: radius of curvature of the lens surface of the second lens component G2 closest to the eyepoint G3R1: radius of curvature of the lens surface closest to the observation object side of the third lens component G3
条件式(5)はコマ収差を良好に補正するため、第2レンズ成分G2の最もアイポイント側のレンズ面の形状と、第3レンズ成分G3の最も観察物体側のレンズ面の形状を規定するものである。第2レンズ成分G2の最もアイポイント側のレンズ面と、第3レンズ成分G3の最も観察物体側のレンズ面は、コマ収差の発生または、補正に大きく影響する。コマ収差を良好に補正するには、第2レンズ成分G2の最もアイポイント側のレンズ面で発生したコマ収差を、第3レンズ成分G3の最も観察物体側のレンズ面で補正することが好ましい。また、コマ収差を良好に補正するには、第2レンズ成分G2の最もアイポイント側のレンズ面の形状と第3レンズ成分G3の最も観察物体側のレンズ面の形状を類似させることにより、第2レンズ成分G2の最もアイポイント側のレンズ面で発生するコマ収差と第3レンズ成分G3の最も観察物体側のレンズ面で補正するコマ収差を類似させ、コマ収差を打ち消すことが望ましい。条件式(5)の下限値を下回ると、第2レンズ成分G2の最もアイポイント側のレンズ面の形状と、第3レンズ成分G3の最も観察物体側のレンズ面の形状の類似性が崩れ、コマ収差が発生するため好ましくない。なお、条件式(5)の効果を確実なものとするために、条件式(5)の下限値を-0.25とすることが望ましい。また、条件式(5)の上限値を上回ると、第2レンズ成分G2の最もアイポイント側のレンズ面の形状と、第3レンズ成分G3の最も観察物体側のレンズ面の形状の類似性が崩れ、コマ収差が発生するため好ましくない。なお、条件式(5)の効果を確実なものとするために、条件式(5)の上限値を0.25、更に-0.20とすることがより望ましい。 Conditional expression (5) prescribes the shape of the lens surface of the second lens component G2 closest to the eye point and the shape of the lens surface of the third lens component G3 closest to the observation object in order to satisfactorily correct coma. It is. The lens surface of the second lens component G2 closest to the eye point and the lens surface of the third lens component G3 closest to the observation object greatly affect the occurrence or correction of coma. In order to satisfactorily correct coma, it is preferable to correct coma generated on the lens surface of the second lens component G2 closest to the eye point with the lens surface of the third lens component G3 closest to the observation object. In order to satisfactorily correct coma aberration, the shape of the lens surface of the second lens component G2 closest to the eye point and the shape of the lens surface of the third lens component G3 closest to the observation object are made similar to each other. It is desirable to make the coma generated on the lens surface of the second lens component G2 closest to the eye point similar to the coma aberration to be corrected on the lens surface of the third lens component G3 closest to the observation object, and cancel the coma. If the lower limit of conditional expression (5) is exceeded, the similarity between the shape of the lens surface of the second lens component G2 closest to the eye point and the shape of the lens surface of the third lens component G3 closest to the observation object is lost. This is not preferable because it causes coma aberration. In order to ensure the effect of conditional expression (5), it is desirable to set the lower limit of conditional expression (5) to -0.25. When the upper limit of conditional expression (5) is exceeded, the similarity between the shape of the lens surface of the second lens component G2 closest to the eye point and the shape of the lens surface of the third lens component G3 closest to the observation object is reduced. It is not preferable because it collapses and coma aberration occurs. In order to ensure the effect of conditional expression (5), it is more desirable to set the upper limit of conditional expression (5) to 0.25, more preferably -0.20.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(6)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (6).
-0.75<(G1R2+G1R1)/(G1R2-G1R1)<0.00 (6)
但し、
G1R1:第1レンズ成分G1の最も観察物体側のレンズ面の曲率半径
G1R2:第1レンズ成分G1の最もアイポイント側のレンズ面の曲率半径
-0.75<(G1R2+G1R1)/(G1R2-G1R1)<0.00 (6)
however,
G1R1: radius of curvature of the lens surface of the first lens component G1 closest to the observation object side G1R2: radius of curvature of the lens surface closest to the eye point of the first lens component G1
条件式(6)は、観察倍率を大きくするとともに、像面湾曲と歪曲収差を良好に補正するため、第1レンズ成分G1の形状を規定するものである。第1レンズ成分G1の正の屈折力は、像面湾曲を発生させるが、第2レンズ成分G2の負の屈折力で発生した像面湾曲を補正する構造となっている。第1レンズ成分G1の最もアイポイント側のレンズ面の屈折力を強くすると、第1レンズ成分G1で発生する像面湾曲が大きくなるため、第2レンズ成分G2の負の屈折力では補正しきれなくなる。一方で、観察倍率を大きくするためには、第1レンズ成分G1の正の屈折力を大きくする必要があるため、第1レンズ成分G1の最も観察物体側のレンズ面の正の屈折力を適量に大きくしなければならない。但し、第1レンズ成分G1の最も観察物体側のレンズ面の正の屈折力を大きくしすぎると、歪曲収差が悪化する。条件式(6)の上限値を上回ると、第1レンズ成分G1の屈折力が大きくなりすぎるため、歪曲収差が悪化するので好ましくない。なお、条件式(6)の効果を確実なものとするために、条件式(6)の上限値を-0.20、更に-0.30とすることがより望ましい。また、条件式(6)の下限値を下回ると、第1レンズ成分G1の屈折力が弱くなり、観察倍率を大きくすることができない。また、条件式(6)の下限値を下回った状態で、観察倍率を大きくすると、第1レンズ成分G1の最もアイポイント側のレンズ面の屈折力が大きくなるため、像面湾曲が悪化するので好ましくない。なお、条件式(6)の効果を確実なものとするために、条件式(6)の下限値を-0.57、更に-0.56、更に-0.50とすることがより望ましい。 Conditional expression (6) defines the shape of the first lens component G1 in order to increase the observation magnification and satisfactorily correct field curvature and distortion. The positive refractive power of the first lens component G1 causes curvature of field, and the structure corrects the curvature of field caused by the negative refractive power of the second lens component G2. If the refractive power of the lens surface closest to the eye point of the first lens component G1 is increased, the curvature of field generated by the first lens component G1 becomes large. Gone. On the other hand, in order to increase the observation magnification, it is necessary to increase the positive refractive power of the first lens component G1. must be increased to However, if the positive refractive power of the lens surface closest to the observation object side of the first lens component G1 is increased too much, the distortion will be worsened. Exceeding the upper limit of conditional expression (6) is not preferable because the refractive power of the first lens component G1 becomes too large, resulting in deterioration of distortion. In order to ensure the effect of conditional expression (6), it is more desirable to set the upper limit of conditional expression (6) to -0.20, more preferably -0.30. If the lower limit of conditional expression (6) is not reached, the refractive power of the first lens component G1 becomes weak, and the observation magnification cannot be increased. If the observation magnification is increased while the lower limit of conditional expression (6) is not reached, the refractive power of the lens surface closest to the eye point of the first lens component G1 increases, and field curvature worsens. I don't like it. In order to ensure the effect of conditional expression (6), it is more desirable to set the lower limit of conditional expression (6) to −0.57, more preferably −0.56, more preferably −0.50.
また、本実施形態に係る接眼光学系ELは、第1レンズ成分G1の最も観察物体側のレンズ面を回転対称非球面にすることにより、歪曲収差を補正することができ、第1レンズ成分G1の最も観察物体側のレンズ面の屈折力を強くすることが可能となり、観察倍率の高倍率化に有利になる。 Further, in the eyepiece optical system EL according to the present embodiment, the lens surface closest to the observation object side of the first lens component G1 is a rotationally symmetric aspherical surface, so that distortion can be corrected. It is possible to increase the refractive power of the lens surface closest to the object to be observed, which is advantageous for increasing the observation magnification.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(7)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (7).
-1.00 < fe/EnP < -0.48 (7)
但し、
fe:当該接眼光学系ELの全系の焦点距離
EnP:基準視度における、当該接眼光学系ELの入射瞳位置(符号は、観察物体面を基準に、アイポイント側を正とする)
-1.00 < fe/EnP < -0.48 (7)
however,
fe: focal length of the entire system of the eyepiece optical system EL EnP: entrance pupil position of the eyepiece optical system EL at the reference diopter (the sign is positive on the eyepoint side with respect to the observation object plane)
条件式(7)は、アイポイントを長く保ちつつ、観察倍率を大きくするため、入射瞳位置を規定するものである。高像高の主光線の通過高を観察物体面に近い領域で高くすることで、アイポイントを長く保ちつつ観察倍率を大きくすることが容易となる。観察物体面に近い領域で高像高の主光線の通過高を高くするためには、入射瞳距離を観察物体面からアイポイント側とは反対の近い距離に設定することが有効である。条件式(7)の上限値を上回ると、入射瞳位置が観察物体から離れるため、高像高の主光線の通過高を高くすることができなくなるため、アイポイントを長く保ちつつ高倍率化することが不可能となるため好ましくない。なお、条件式(7)の効果を確実なものとするために、条件式(7)の上限値を-0.50とすることが望ましい。また、条件式(7)の下限値を下回ると、入射瞳位置が観察物体に近づきすぎるため、第1レンズ成分G1の高像高の主光線通過高が高くなり、像面湾曲を大きく発生してしまうため好ましくない。なお、条件式(7)の効果を確実なものとするために、条件式(7)の下限値を-0.70、更に-0.65とすることがより望ましい。 Conditional expression (7) defines the position of the entrance pupil in order to increase the observation magnification while keeping the eye point long. By increasing the passage height of the principal ray of high image height in a region close to the observation object plane, it becomes easy to increase the observation magnification while maintaining a long eye point. In order to increase the passing height of the principal ray of high image height in the region close to the observation object plane, it is effective to set the entrance pupil distance to a short distance from the observation object plane opposite to the eye point side. If the upper limit of conditional expression (7) is exceeded, the position of the entrance pupil moves away from the observation object, and the passage height of the principal ray of high image height cannot be increased. This is not desirable because it makes it impossible to In order to ensure the effect of conditional expression (7), it is desirable to set the upper limit of conditional expression (7) to −0.50. If the lower limit of conditional expression (7) is not reached, the entrance pupil position is too close to the observed object, so that the height of the principal ray passing through the high image height of the first lens component G1 increases, resulting in large curvature of field. It is not preferable because In order to ensure the effect of conditional expression (7), it is more desirable to set the lower limit of conditional expression (7) to -0.70, more preferably -0.65.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(8)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (8).
-0.40 < fe/f23 < -0.15 (8)
但し、
fe:当該接眼光学系ELの全系の焦点距離
f23:第2レンズ成分G2と第3レンズ成分G3との合成焦点距離
-0.40<fe/f23<-0.15 (8)
however,
fe: focal length of the entire eyepiece optical system EL f23: combined focal length of the second lens component G2 and the third lens component G3
条件式(8)は、第2レンズ成分G2と第3レンズ成分G3の光軸がずれて製造された場合に、収差性能の悪化を小さくするため、第2レンズ成分G2と第3レンズ成分G3の合成焦点距離と接眼光学系ELの全系の焦点距離との比を規定するものである。第2レンズ成分G2と第3レンズ成分G3の合成焦点距離を、接眼光学系ELの全系の焦点距離に対し小さくすることで、製造誤差により第2レンズ成分G2と第3レンズ成分G3の光軸がずれた場合でも収差性能の悪化を小さくすることができる。また、温度変化による第2レンズ成分G2と第3レンズ成分G3の屈折率または、曲率半径が変化した場合の光学性能の悪化を小さくすることが可能になる。特に、第2レンズ成分G2と第3レンズ成分G3が光学樹脂で構成されている場合、有効となる。この条件式(8)の下限値を下回ると、第2レンズ成分G2と第3レンズ成分G3の負の合成屈折力が強くなり、製造誤差における収差性能の悪化が大きくなるため好ましくない。なお、条件式(8)の効果を確実なものとするために、条件式(8)の下限値を-0.35とすることが望ましい。また、条件式(8)の上限値を上回ると、第2レンズ成分G2の負の屈折力が小さくなり、像面湾曲の補正が不十分となるため好ましくない。なお、条件式(8)の効果を確実なものとするために、条件式(8)の上限値を-0.20、更に-0.25とすることがより望ましい。 Conditional expression (8) reduces the deterioration of aberration performance when the optical axes of the second lens component G2 and the third lens component G3 are misaligned. and the focal length of the entire ocular optical system EL. By making the combined focal length of the second lens component G2 and the third lens component G3 smaller than the focal length of the entire eyepiece optical system EL, the light of the second lens component G2 and the third lens component G3 is Deterioration of aberration performance can be reduced even when the axis is deviated. Further, deterioration of optical performance when the refractive index or the radius of curvature of the second lens component G2 and the third lens component G3 changes due to temperature change can be reduced. This is particularly effective when the second lens component G2 and the third lens component G3 are made of optical resin. If the lower limit of conditional expression (8) is not reached, the combined negative refractive power of the second lens component G2 and the third lens component G3 becomes strong, and the deterioration of aberration performance due to manufacturing errors becomes large, which is not preferable. In order to ensure the effect of conditional expression (8), it is desirable to set the lower limit of conditional expression (8) to -0.35. Moreover, if the upper limit of conditional expression (8) is exceeded, the negative refractive power of the second lens component G2 becomes small, and correction of curvature of field becomes insufficient, which is not preferable. In order to ensure the effect of conditional expression (8), it is more desirable to set the upper limit of conditional expression (8) to -0.20, more preferably -0.25.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(9)を満足することが望ましい。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (9).
0.58 < D1/f1 < 0.90 (9)
但し、
D1:基準視度における、観察物体から第1レンズ成分G1の最も観察物体側のレンズ面までの空気換算距離
f1:第1レンズ成分G1の焦点距離
0.58<D1/f1<0.90 (9)
however,
D1: Air-converted distance from the observed object to the lens surface of the first lens component G1 closest to the observed object, in the standard diopter f1: Focal length of the first lens component G1
条件式(9)は、コマ収差を良好に補正するため、基準視度における観察物体から第1レンズ成分G1の最も観察物体側のレンズ面までの空気換算距離と第1レンズ成分G1の焦点距離の比を規定するものである。基準視度における、観察物体から第1レンズ成分G1の最も観察物体側のレンズ面までの空気換算距離が大きくなると、観察面上の一点から射出した光束は、第1レンズ成分G1上で通過高が大きく変化する。そのため、観察物体から第1レンズ成分G1の最も観察物体側のレンズ面までの空気換算距離D1が大きくなると第1レンズ成分G1の正の屈折力によりコマ収差が大きく発生するため、第1レンズ成分G1の屈折力を小さくする必要がある。一方で、第1レンズ成分G1の屈折力を大きくするためには、第1レンズ成分G1で発生するコマ収差を小さくするため、観察物体から第1レンズ成分G1の最も観察物体側のレンズ面までの空気換算距離D1を小さくする必要がある。条件式(9)の上限値を上回ると、観察物体から第1レンズ成分G1の最も観察物体側のレンズ面までの空気換算距離D1に対し、第1レンズ成分G1の屈折力が強くなり、コマ収差が悪化するため好ましくない。なお、条件式(9)の効果を確実なものとするために、条件式(9)の上限値を0.71、更に0.68とすることがより望ましい。また、条件式(9)の下限値を下回ると、第1レンズ成分G1の正の屈折力が弱くなり、観察倍率の高倍率化が不可能となるため好ましくない。なお、条件式(9)の効果を確実なものとするために、条件式(9)の下限値を0.60、更に0.63とすることがより望ましい。 In order to satisfactorily correct coma aberration, conditional expression (9) defines the air-converted distance from the observation object at the reference diopter to the lens surface of the first lens component G1 closest to the observation object and the focal length of the first lens component G1. It defines the ratio of When the air-converted distance from the observation object to the lens surface of the first lens component G1 closest to the observation object at the standard diopter becomes large, the luminous flux emitted from one point on the observation surface reaches a passing height on the first lens component G1. changes significantly. Therefore, when the air-converted distance D1 from the observation object to the lens surface of the first lens component G1 closest to the observation object increases, the positive refractive power of the first lens component G1 causes large coma aberration. It is necessary to reduce the refractive power of G1. On the other hand, in order to increase the refractive power of the first lens component G1, in order to reduce the coma generated in the first lens component G1, the distance from the observation object to the lens surface of the first lens component G1 closest to the observation object side is It is necessary to reduce the air conversion distance D1 of . If the upper limit of conditional expression (9) is exceeded, the refracting power of the first lens component G1 becomes stronger with respect to the air-converted distance D1 from the observation object to the lens surface of the first lens component G1 closest to the observation object. This is not preferable because it worsens aberrations. In order to ensure the effect of conditional expression (9), it is more desirable to set the upper limit of conditional expression (9) to 0.71, more preferably 0.68. If the lower limit of conditional expression (9) is not reached, the positive refractive power of the first lens component G1 becomes weak, making it impossible to increase the observation magnification, which is not preferable. In order to ensure the effect of conditional expression (9), it is more desirable to set the lower limit of conditional expression (9) to 0.60, more preferably 0.63.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(10)を満足することが望ましい。なお、当該接眼光学系ELの全長は、観察物体Oから当該接眼光学系ELの最もアイポイント側のレンズ面までの光軸上の距離である。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (10). The total length of the eyepiece optical system EL is the distance on the optical axis from the observation object O to the lens surface of the eyepiece optical system EL closest to the eye point.
1.50 < TL/fe < 1.80 (10)
但し、
TL:当該接眼光学系ELの全長
fe:当該接眼光学系ELの全系の焦点距離
1.50 < TL/fe < 1.80 (10)
however,
TL: total length of the eyepiece optical system EL fe: focal length of the entire eyepiece optical system EL
条件式(10)は、像面湾曲を補正するため、当該接眼光学系ELの全長と全系の焦点距離の比を規定するものである。条件式(10)の下限値を下回ると、当該接眼光学系ELの全体の屈折力が弱くなり観察倍率を上げられないため好ましくない。なお、この条件式(10)の効果を確実なものとするために、条件式(10)の下限値を1.55、更に1.60とすることがより望ましい。また、条件式(10)の上限値を上回ると、像面湾曲が悪化するため好ましくない。なお、この条件式(10)の効果を確実なものとするために、条件式(10)の上限値を1.70とすることが望ましい。 Conditional expression (10) defines the ratio between the total length of the eyepiece optical system EL and the focal length of the entire system in order to correct field curvature. If the lower limit of conditional expression (10) is not reached, the refractive power of the eyepiece optical system EL as a whole becomes weak and the observation magnification cannot be increased, which is not preferable. In order to ensure the effect of conditional expression (10), it is more desirable to set the lower limit of conditional expression (10) to 1.55, more preferably 1.60. Moreover, if the upper limit of conditional expression (10) is exceeded, the curvature of field worsens, which is not preferable. In order to ensure the effect of conditional expression (10), it is desirable to set the upper limit of conditional expression (10) to 1.70.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(11)を満足することが望ましい。なお、第1レンズ成分G1が接合レンズで構成されていて、複数のレンズ要素を有するときは、それらのレンズ要素の少なくとも1つが条件式(11)を満足する。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (11). When the first lens component G1 is composed of a cemented lens and has a plurality of lens elements, at least one of those lens elements satisfies conditional expression (11).
1.550 < nd1 < 1.800 (11)
但し、
nd1:第1レンズ成分G1を構成するレンズ要素の媒質のd線に対する屈折率
1.550 < nd1 < 1.800 (11)
however,
nd1: refractive index for the d-line of the medium of the lens element constituting the first lens component G1
条件式(11)は、歪曲収差、像面湾曲を良好に補正するため、第1レンズ成分G1を構成するレンズ要素の媒質のd線に対する屈折率を規定するものである。条件式(11)の下限値を下回ると、第1レンズ成分G1に屈折力を持たすことができず、性能を維持して高倍率化をすることが難しいので好ましくない。なお、条件式(11)の効果を確実なものとするために、条件式(11)の下限値を1.600、更に1.700とすることがより望ましい。また、条件式(11)の上限値を上回ると、歪曲収差が悪化するため好ましくない。なお、条件式(11)の効果を確実なものとするために、条件式(11)の上限値を1.850とすることが望ましい。 Conditional expression (11) defines the refractive index for the d-line of the medium of the lens element forming the first lens component G1 in order to satisfactorily correct distortion and curvature of field. If the lower limit of conditional expression (11) is not reached, the first lens component G1 cannot have refractive power, and it is difficult to maintain the performance and increase the magnification, which is not preferable. In order to ensure the effect of conditional expression (11), it is more desirable to set the lower limit of conditional expression (11) to 1.600, more preferably 1.700. Moreover, if the upper limit of conditional expression (11) is exceeded, the distortion deteriorates, which is not preferable. In order to ensure the effect of conditional expression (11), it is desirable to set the upper limit of conditional expression (11) to 1.850.
また、本実施形態に係る接眼光学系ELは、以下に示す条件式(12)を満足することが望ましい。なお、第2レンズ成分G2が接合レンズで構成されていて、複数のレンズ要素を有するときは、それらのレンズ要素の少なくとも1つが条件式(12)を満足する。 Moreover, it is desirable that the eyepiece optical system EL according to the present embodiment satisfies the following conditional expression (12). When the second lens component G2 is composed of a cemented lens and has a plurality of lens elements, at least one of the lens elements satisfies conditional expression (12).
1.640 < nd2 < 1.800 (9)
但し、
nd2:第2レンズ成分G2を構成するレンズ要素の媒質のd線に対する屈折率
1.640 < nd2 < 1.800 (9)
however,
nd2: refractive index for the d-line of the medium of the lens element constituting the second lens component G2
条件式(12)は、非点収差を良好に補正するため、第2レンズ成分G2を構成するレンズ要素の媒質のd線に対する屈折率を規定するものである。条件式(12)の下限値を下回ると、第2レンズ成分G2の偏芯により光学性能が劣化するため好ましくない。なお、条件式(12)の効果を確実なものとするために、条件式(12)の下限値を1.650とすることが望ましい。また、条件式(12)の上限値を上回ると、非点収差の補正が困難になるため好ましくない。なお、条件式(12)の効果を確実なものとするために、条件式(12)の上限値を1.750とすることが望ましい。 Conditional expression (12) defines the refractive index of the medium of the lens elements forming the second lens component G2 for the d-line in order to correct astigmatism satisfactorily. If the lower limit of conditional expression (12) is not reached, the optical performance is degraded due to decentering of the second lens component G2, which is not preferable. In order to ensure the effect of conditional expression (12), it is desirable to set the lower limit of conditional expression (12) to 1.650. On the other hand, if the upper limit of conditional expression (12) is exceeded, it becomes difficult to correct astigmatism, which is not preferable. In order to ensure the effect of conditional expression (12), it is desirable to set the upper limit of conditional expression (12) to 1.750.
また、本実施形態に係る接眼光学系ELは、第1レンズ成分G1、第2レンズ成分G2、第3レンズ成分G3、第4レンズ成分G4を単レンズ構成にし、4枚の単レンズで構成しても十分に良好な収差性能を達成することができる。 The eyepiece optical system EL according to the present embodiment is composed of four single lenses, each of which is composed of a single lens composed of the first lens component G1, the second lens component G2, the third lens component G3, and the fourth lens component G4. sufficiently good aberration performance can be achieved.
また、本実施形態に係る接眼光学系ELは、接眼光学系全体を光軸方向に移動させることにより視度調節を容易に行うことができる。 Further, the eyepiece optical system EL according to the present embodiment can easily adjust the dioptric power by moving the entire eyepiece optical system in the optical axis direction.
なお、以上で説明した条件及び構成は、それぞれが上述した効果を発揮するものであり、全ての条件及び構成を満たすものに限定されることはなく、いずれかの条件又は構成、或いは、いずれかの条件又は構成の組み合わせを満たすものでも、上述した効果を得ることが可能である。 In addition, the conditions and configurations described above exhibit the effects described above, and are not limited to those that satisfy all the conditions and configurations. It is possible to obtain the above-described effects even if the conditions or combinations of the above conditions are satisfied.
次に、本実施形態に係る接眼光学系ELを備えた光学機器(撮像装置)であるカメラを図23に基づいて説明する。このカメラ1は、対物レンズ(撮影レンズ)OLを備えたレンズ交換式の所謂ミラーレスカメラである。本カメラ1において、不図示の物体(被写体)からの光は、対物レンズOLで集光されて、不図示のOLPF(Optical low pass filter:光学ローパスフィルタ)を介して撮像部Cの撮像面上に被写体像を形成する。そして、撮像部Cに設けられた光電変換素子により被写体像が光電変換されて被写体の画像が生成される。この画像は、カメラ1に設けられた電子ビューファインダEVF(Electronic view finder)に表示される。ここで、電子ビューファインダEVFは、液晶表示素子等の画像表示素子DPと、この画像表示素子DPの表示面(上述した観察物体O)に表示された画像を拡大観察するための接眼光学系ELとを有して構成される。これにより撮影者は、アイポイントEPに眼を位置させることにより、接眼光学系ELを介して対物レンズOLにより形成される物体(被写体)の像を観察することができる。 Next, a camera, which is an optical device (imaging device) equipped with the eyepiece optical system EL according to this embodiment, will be described with reference to FIG. This camera 1 is a so-called mirrorless camera with interchangeable lenses that includes an objective lens (photographing lens) OL. In the camera 1, light from an unillustrated object (subject) is condensed by an objective lens OL and passes through an unillustrated OLPF (Optical low pass filter) on the imaging surface of the imaging unit C. to form an image of the subject. Then, the subject image is photoelectrically converted by the photoelectric conversion element provided in the imaging section C to generate the subject image. This image is displayed on an electronic viewfinder EVF (Electronic view finder) provided in the camera 1 . Here, the electronic viewfinder EVF includes an image display element DP such as a liquid crystal display element, and an eyepiece optical system EL for magnifying and observing an image displayed on the display surface of the image display element DP (observation object O described above). and Accordingly, the photographer can observe an image of an object (subject) formed by the objective lens OL through the eyepiece optical system EL by positioning the eye at the eye point EP.
また、撮影者によって不図示のレリーズボタンが押されると、撮像部Cにより光電変換された画像が不図示のメモリに記憶される。このようにして、撮影者は本カメラ1による被写体の撮影を行うことができる。なお、本実施形態では、ミラーレスカメラの例を説明したが、カメラ本体にクイックリターンミラーを有しファインダー光学系により被写体を観察する一眼レフタイプのカメラに本実施形態に係る接眼光学系ELを搭載した場合でも、上記カメラ1と同様の効果を奏することができる。 Further, when a release button (not shown) is pressed by the photographer, an image photoelectrically converted by the imaging section C is stored in a memory (not shown). In this manner, the photographer can photograph the subject with the camera 1. FIG. In this embodiment, an example of a mirrorless camera has been described. Even when it is mounted, the same effects as those of the camera 1 can be obtained.
このように、本実施形態に係る接眼光学系ELは、像を拡大観察するための光学系(接眼レンズ)である。ここで像とは、対物レンズによる中間像、または液晶表示素子、有機ELディスプレイ等の画像表示素子の表示面であり、特に有機ELディスプレイの表示面であることが好ましい。したがって、本実施形態に係る接眼光学系ELは、例えば、表示面に表示された像を観察するための電子双眼鏡、ヘッドマウントディスプレイ、カメラの内臓又は外付けの電子ビューファインダの接眼レンズに用いることに適している。 Thus, the eyepiece optical system EL according to this embodiment is an optical system (eyepiece lens) for magnifying and observing an image. Here, the image means an intermediate image formed by an objective lens or a display surface of an image display device such as a liquid crystal display device or an organic EL display, and particularly preferably the display surface of an organic EL display. Therefore, the eyepiece optical system EL according to the present embodiment can be used, for example, as an eyepiece lens for an electronic binocular for observing an image displayed on a display surface, a head-mounted display, or an electronic viewfinder built-in or external to a camera. Suitable for
なお、図1等には図示していないが、観察物体O(図23に示す画像表示素子DPの表示面)と第1レンズ成分G1との間には、カバーガラス、プリズム等の光学部材が配置されていてもよい。また、第4レンズ成分G4とアイポイントEPとの間にも、カバーガラス等の光学部材が配置されていてもよい。 Although not shown in FIG. 1 and the like, an optical member such as a cover glass or a prism is provided between the observation object O (the display surface of the image display element DP shown in FIG. 23) and the first lens component G1. may be placed. Also, an optical member such as a cover glass may be arranged between the fourth lens component G4 and the eyepoint EP.
以下、本実施形態に係る接眼光学系ELの製造方法の概略を、図24を参照して説明する。まず、各レンズを配置して、正の屈折力を有する第1レンズ成分G1、負の屈折力を有する第2レンズ成分G2、正の屈折力を有する第3レンズ成分G3、及び、正の屈折力を有する第4レンズ成分とG4をそれぞれ準備する(ステップS100)。そして、所定の条件式(例えば、上述した条件式(1)や条件式(2))による条件を満足するように配置する(ステップS200)。 The outline of the manufacturing method of the eyepiece optical system EL according to this embodiment will be described below with reference to FIG. First, the lenses are arranged to form a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, a third lens component G3 having positive refractive power, and a positive refractive power. A fourth lens component having power and G4 are prepared (step S100). Then, they are arranged so as to satisfy a condition based on a predetermined conditional expression (for example, conditional expression (1) or conditional expression (2) described above) (step S200).
具体的には、本実施形態では、例えば図1に示すように、観察物体側から順に、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11を配置して第1レンズ成分G1とし、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12を配置して第2レンズ成分G2とし、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31を配置して第3レンズ成分G3とし、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41を配置して第4レンズ成分G4とする。このようにして準備した各レンズ成分を上述した手順で配置して接眼光学系ELを製造する。 Specifically, in this embodiment, for example, as shown in FIG. 1, a biconvex positive lens shape in which the lens surface on the observation object side and the lens surface on the eye point side are formed in an aspherical shape in order from the observation object side. is arranged to form a first lens component G1, the lens surface on the observation object side and the lens surface on the eyepoint side are formed in an aspherical shape, and the concave surface faces the observation object side in a negative meniscus lens shape. is arranged to form a second lens component G2, the lens surface on the observation object side and the lens surface on the eye point side are formed in an aspheric shape, and the positive meniscus lens shape with the concave surface facing the object side is formed. The aspherical positive lens L31 is arranged as the third lens component G3, and the lens surface on the observation object side and the lens surface on the eye point side are formed in an aspherical shape, and the positive meniscus lens shape with the concave surface facing the observation object side is formed. An aspherical positive lens L41 is arranged as a fourth lens component G4. The eyepiece optical system EL is manufactured by arranging the lens components prepared in this way according to the procedure described above.
以上のような構成により、観察倍率が大きく、良好な光学性能を有する接眼光学系EL、この接眼光学系ELを有する光学機器(撮像装置)及び接眼光学系ELの製造方法を提供することができる。 With the configuration described above, it is possible to provide an eyepiece optical system EL having a large observation magnification and excellent optical performance, an optical apparatus (imaging device) having the eyepiece optical system EL, and a method for manufacturing the eyepiece optical system EL. .
以下、本願の各実施例を、図面に基づいて説明する。なお、図1、図3、図5、図7、図9、図11、図13、図15、図17、図19及び図21は、各実施例に係る接眼光学系EL(EL1~EL11)の構成及び屈折力配分を示す断面図である。 Each embodiment of the present application will be described below with reference to the drawings. 1, 3, 5, 7, 9, 11, 13, 15, 17, 19 and 21 show the eyepiece optical system EL (EL1 to EL11) according to each embodiment. is a cross-sectional view showing the configuration and refractive power distribution of the .
これらの実施例において、非球面は、光軸に垂直な方向の高さをyとし、高さyにおける各非球面の頂点の接平面から各非球面までの光軸に沿った距離(サグ量)をS(y)とし、基準球面の曲率半径(近軸曲率半径)をrとし、円錐定数をKとし、n次の非球面係数をAnとしたとき、以下の式(a)で表される。なお、以降の実施例において、「E-n」は「×10-n」を示す。 In these embodiments, the aspheric surface has a height y in the direction perpendicular to the optical axis, and the distance (sag amount ) is S(y), the radius of curvature of the reference sphere (the paraxial radius of curvature) is r, the conic constant is K, and the n-th order aspheric coefficient is An, then the following formula (a) is obtained: be. In the following examples, "En" indicates "×10 -n ".
S(y)=(y2/r)/{1+(1-K×y2/r2)1/2}
+A4×y4+A6×y6+A8×y8+A10×y10+A12×y12 (a)
S(y)=(y 2 /r)/{1+(1−K×y 2 /r 2 ) 1/2 }
+A4× y4 +A6× y6 +A8× y8 +A10× y10 +A12× y12 (a)
なお、各実施例において、2次の非球面係数A2は0である。また、各実施例の表中において、非球面には面番号の右側に*印を付している。 In each embodiment, the second-order aspheric coefficient A2 is zero. In addition, in the tables of each example, an asterisk (*) is attached to the right side of the surface number of an aspherical surface.
[第1実施例]
図1は、第1実施例に係る接眼光学系EL1の構成を示す図である。この接眼光学系EL1は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[First embodiment]
FIG. 1 is a diagram showing the configuration of an eyepiece optical system EL1 according to the first embodiment. The eyepiece optical system EL1 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL1において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL1, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with a concave surface facing the observation object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. It is The third lens component G3 is composed of an aspherical positive lens L31 having a positive meniscus lens shape with a concave surface facing the object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. ing. The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL1における視度調整は、接眼光学系EL1全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL1 is performed by moving the entire eyepiece optical system EL1 in the optical axis direction.
以下の表1に、接眼光学系EL1の諸元の値を掲げる。この表1において、全体諸元に示すfeは全系の焦点距離、Hは最大物体高、TLは全長の値を示している。また、レンズデータにおける第1欄mは、光線の進行する方向に沿った物体側からのレンズ面の順序(面番号)を、第2欄rは、各レンズ面の曲率半径を、第3欄dは、各光学面から次の光学面までの光軸上の距離(面間隔)を、第4欄nd及び第5欄νdは、d線(λ=587.6nm)に対する屈折率及びアッベ数を示している。また、曲率半径∞は平面を示し、空気の屈折率1.00000は省略してある。また、物面が観察物体Oを示し、像面がアイポイントEPを示している。 Table 1 below lists the values of the specifications of the eyepiece optical system EL1. In Table 1, fe shown in the overall specifications is the focal length of the entire system, H is the maximum object height, and TL is the total length. In addition, the first column m in the lens data indicates the order (surface number) of the lens surfaces from the object side along the direction in which light rays travel, the second column r indicates the radius of curvature of each lens surface, and the third column d is the distance (surface distance) on the optical axis from each optical surface to the next optical surface, and the fourth column nd and fifth column νd are the refractive index and Abbe number for the d-line (λ = 587.6 nm). is shown. Also, the radius of curvature ∞ indicates a plane, and the refractive index of air, 1.00000, is omitted. Also, the object plane indicates the observed object O, and the image plane indicates the eyepoint EP.
ここで、以下の全ての諸元値において掲載されている焦点距離f(fOe,fEe等)、曲率半径r、面間隔d、その他長さの単位は一般に「mm」が使われるが、光学系は、比例拡大または比例縮小しても同等の光学性能が得られるので、これに限られるものではない。また、これらの符号の説明及び諸元表の説明は以降の実施例においても同様である。 Here, the focal length f (fOe, fEe, etc.), curvature radius r, surface spacing d, and other lengths listed in all the following specification values are generally expressed in units of "mm". is not limited to this because equivalent optical performance can be obtained even if it is proportionally enlarged or proportionally reduced. Further, the explanation of these symbols and the explanation of the specification table are the same in the following embodiments.
なお、上述したように、本実施例を含む以降の各実施例では図示していないが、観察物体Oと第1レンズ成分G1との間や、第4レンズ成分G4とアイポイントEPとの間に、カバーガラス、プリズム、表示カバーガラス等の光学部材が配置されている場合は、上記面間隔dは空気換算長とする。 As described above, although not shown in each of the following embodiments including the present embodiment, the distance between the observation object O and the first lens component G1 and between the fourth lens component G4 and the eye point EP When optical members such as a cover glass, a prism, and a display cover glass are arranged, the surface distance d is an air conversion length.
(表1)第1実施例
[全体諸元]
fe = 17.641
H = 6.30
TL = 28.790
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 29.01673 6.95 1.77377 47.25
2* -11.37822 3.03
3* -6.74812 1.50 1.63550 23.89
4* -58.92577 1.25
5* -48.01803 5.40 1.53110 55.91
6* -10.14569 0.50
7* -1037.93340 2.75 1.53110 55.91
8* -42.12958 D2
像面 ∞
(Table 1) First embodiment [overall specifications]
fe = 17.641
H = 6.30
TL = 28.790
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 29.01673 6.95 1.77377 47.25
2* -11.37822 3.03
3* -6.74812 1.50 1.63550 23.89
4* -58.92577 1.25
5* -48.01803 5.40 1.53110 55.91
6* -10.14569 0.50
7* -1037.93340 2.75 1.53110 55.91
8* -42.12958 D2
Image plane ∞
この接眼光学系EL1において、第1面、第2面、第3面、第4面、第5面、第6面、第7面及び第8面は非球面形状に形成されている。次の表2に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL1, the first, second, third, fourth, fifth, sixth, seventh and eighth surfaces are aspherical. Table 2 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表2)
[非球面データ]
第1面
K=-1.0414
A4 =-1.29144E-04 A6 =-4.67158E-07 A8 = 1.78024E-08
A10=-1.65828E-10 A12= 6.30320E-13
第2面
K=-2.2911
A4 =-1.46042E-04 A6 = 1.05047E-06 A8 =-8.71894E-09
A10= 3.48401E-11 A12= 0.00000E+00
第3面
K=-0.2684
A4 = 3.35859E-04 A6 =-4.37805E-06 A8 = 2.17895E-08
A10=-4.94107E-11 A12= 0.00000E+00
第4面
K= 5.9869
A4 = 9.81668E-05 A6 =-1.20860E-06 A8 = 6.95819E-09
A10=-1.72138E-11 A12= 0.00000E+00
第5面
K=5.9905
A4 = 2.82487E-05 A6 = 1.16190E-06 A8 =-1.23653E-08
A10= 4.18910E-11 A12= 0.00000E+00
第6面
K= 0.3916
A4 = 1.91131E-04 A6 =-3.21702E-07 A8 =-3.26701E-09
A10= 2.35655E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.52684E-04 A6 = 1.49017E-06 A8 =-1.20661E-08
A10= 5.44999E-11 A12= 0.00000E+00
第8面
K= 3.6084
A4 =-2.40943E-04 A6 = 2.55221E-06 A8 =-1.68422E-08
A10= 5.77483E-11 A12= 0.00000E+00
(Table 2)
[Aspheric data]
1st surface K=-1.0414
A4 = -1.29144E-04 A6 = -4.67158E-07 A8 = 1.78024E-08
A10 = -1.65828E-10 A12 = 6.30320E-13
2nd surface K=-2.2911
A4 = -1.46042E-04 A6 = 1.05047E-06 A8 = -8.71894E-09
A10= 3.48401E-11 A12= 0.00000E+00
3rd surface K=-0.2684
A4 = 3.35859E-04 A6 = -4.37805E-06 A8 = 2.17895E-08
A10 = -4.94107E-11 A12 = 0.00000E+00
4th surface K = 5.9869
A4 = 9.81668E-05 A6 = -1.20860E-06 A8 = 6.95819E-09
A10 = -1.72138E-11 A12 = 0.00000E+00
5th surface K=5.9905
A4 = 2.82487E-05 A6 = 1.16190E-06 A8 = -1.23653E-08
A10= 4.18910E-11 A12= 0.00000E+00
6th surface K = 0.3916
A4 = 1.91131E-04 A6 = -3.21702E-07 A8 = -3.26701E-09
A10= 2.35655E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.52684E-04 A6 = 1.49017E-06 A8 = -1.20661E-08
A10= 5.44999E-11 A12= 0.00000E+00
8th surface K = 3.6084
A4 = -2.40943E-04 A6 = 2.55221E-06 A8 = -1.68422E-08
A10= 5.77483E-11 A12= 0.00000E+00
この接眼光学系EL1において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表3に、視度毎の可変間隔及び入射瞳位置を示す。なお、視度は、-1[1/m]を「-1dpt」とし、+2[1/m]を「+2dpt」とし、-4[1/m]を「-4dpt」として表している。以降の実施例においても同様である。 In this eyepiece optical system EL1, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 3 below shows the variable spacing and entrance pupil positions for each dioptric power. The dioptric power is expressed as "-1 dpt" for -1 [1/m], "+2 dpt" for +2 [1/m], and "-4 dpt" for -4 [1/m]. The same applies to the following examples.
(表3)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.41 8.33 6.39
D2 20.60 19.68 21.62
EnP -29.03270 -30.46513 -27.64176
(Table 3)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.41 8.33 6.39
D2 20.60 19.68 21.62
EnP -29.03270 -30.46513 -27.64176
次の表4に、この接眼光学系EL1の各条件式対応値を示す。 Table 4 below shows values corresponding to each conditional expression of the eyepiece optical system EL1.
(表4)
f4 = 82.602
f12= 28.790
f23=-63.706
[条件式対応値]
(1)fe/f1=1.545
(2)fe/f12=0.613
(3)νd2=23.89
(4)fe/f4=0.214
(5)(G2R2-G3R1)/(G2R2+G3R1)= 0.102
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.437
(7)fe/EnP=-0.608
(8)fe/f23=-0.277
(9)D1/f1=0.649
(10)TL/fe=1.632
(11)nd1=1.774
(12)nd2=1.636
(Table 4)
f4 = 82.602
f12 = 28.790
f23=-63.706
[Value corresponding to conditional expression]
(1) fe/f1 = 1.545
(2) fe/f12 = 0.613
(3) νd2 = 23.89
(4) fe/f4 = 0.214
(5) (G2R2-G3R1)/(G2R2+G3R1) = 0.102
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.437
(7) fe/EnP = -0.608
(8) fe/f23=-0.277
(9) D1/f1 = 0.649
(10) TL/fe = 1.632
(11) nd1 = 1.774
(12) nd2 = 1.636
このように、この接眼光学系EL1は、上記条件式(1)~(11)を満足している。 Thus, the eyepiece optical system EL1 satisfies the conditional expressions (1) to (11).
この接眼光学系EL1の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図2に示す。なお、球面収差図と非点収差図の横軸の単位は「1/m」であり、図では「D」で示す。また、コマ収差図と倍率色収差図は角度単位の分を示し、図中のd、gはd線、g線での収差曲線を示している。また、コマ収差図は各物体高に対する収差曲線を示している。これらの説明は以降の実施例においても同様である。これらの各収差図より、この接眼光学系EL1は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 2 shows a spherical aberration diagram, an astigmatism diagram, a distortion diagram, and a coma aberration diagram at the reference diopter (-1 dpt) of this eyepiece optical system EL1. The unit of the horizontal axis of the spherical aberration diagram and the astigmatism diagram is "1/m", which is indicated by "D" in the figure. Also, the coma aberration diagram and the magnification chromatic aberration diagram show the angular unit, and d and g in the diagram show the aberration curves at the d-line and the g-line. Also, the coma aberration diagram shows the aberration curve for each object height. These explanations also apply to the following embodiments. From these aberration diagrams, it can be seen that the eyepiece optical system EL1 achieves good aberrations within the diopter adjustment range.
[第2実施例]
図3は、第2実施例に係る接眼光学系EL2の構成を示す図である。この接眼光学系EL2は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Second embodiment]
FIG. 3 is a diagram showing the configuration of the eyepiece optical system EL2 according to the second embodiment. The eyepiece optical system EL2 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL2において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL2, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with a concave surface facing the observation object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. It is The third lens component G3 is composed of an aspherical positive lens L31 having a positive meniscus lens shape with a concave surface facing the object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. ing. The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL2における視度調整は、接眼光学系EL2全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL2 is performed by moving the entire eyepiece optical system EL2 in the optical axis direction.
以下の表5に、接眼光学系EL2の諸元の値を掲げる。 Table 5 below lists the values of the specifications of the eyepiece optical system EL2.
(表5)第2実施例
[全体諸元]
fe = 18.135
H = 6.30
TL = 28.100
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 18.29768 7.45 1.53110 55.91
2* -8.02783 2.40
3* -5.08738 2.15 1.63550 23.89
4* -16.13188 0.50
5* -46.53675 5.00 1.53110 55.91
6* -9.74321 0.50
7* -62.07807 2.30 1.53110 55.91
8* -36.52997 D2
像面 ∞
(Table 5) Second embodiment [overall specifications]
fe = 18.135
H = 6.30
TL = 28.100
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 18.29768 7.45 1.53110 55.91
2* -8.02783 2.40
3* -5.08738 2.15 1.63550 23.89
4* -16.13188 0.50
5* -46.53675 5.00 1.53110 55.91
6* -9.74321 0.50
7* -62.07807 2.30 1.53110 55.91
8* -36.52997 D2
Image plane ∞
この接眼光学系EL2において、第1面、第2面、第3面、第4面、第5面、第6面、第7面及び第8面は非球面形状に形成されている。次の表6に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL2, the first, second, third, fourth, fifth, sixth, seventh and eighth surfaces are aspherical. Table 6 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表6)
[非球面データ]
第1面
K= 0.4135
A4 =-1.67471E-04 A6 =-2.55937E-06 A8 =4.54261E-08
A10=-3.19957E-10 A12= 1.06400E-12
第2面
K=-2.0545
A4 =-3.02431E-04 A6 = 3.45590E-06 A8 =-3.41508E-08
A10= 1.41269E-10 A12= 0.00000E+00
第3面
K=-0.3061
A4 = 5.48726E-04 A6 =-5.11105E-06 A8 =-4.02571E-10
A10= 6.06422E-11 A12= 0.00000E+00
第4面
K=-3.9720
A4 = 1.64809E-04 A6 =-6.23672E-07 A8 =-3.44304E-09
A10= 4.26001E-12 A12= 0.00000E+00
第5面
K= 5.8883
A4 =-5.24409E-05 A6 = 5.07414E-07 A8 = 3.77890E-09
A10=-1.41672E-11 A12= 0.00000E+00
第6面
K= 0.4195
A4 = 2.57996E-04 A6 =-1.85757E-06 A8 = 2.18453E-09
A10= 5.57891E-11 A12= 0.00000E+00
第7面
K= 4.9451
A4 =-8.67424E-05 A6 = 9.74736E-07 A8 = 5.79036E-09
A10=-6.53413E-11 A12= 0.00000E+00
第8面
K= 5.7525
A4 =-2.08333E-04 A6 = 2.55741E-06 A8 =-6.33475E-09
A10=-2.34517E-11 A12= 0.00000E+00
(Table 6)
[Aspheric data]
1st surface K = 0.4135
A4 = -1.67471E-04 A6 = -2.55937E-06 A8 = 4.54261E-08
A10 = -3.19957E-10 A12 = 1.06400E-12
2nd surface K=-2.0545
A4 = -3.02431E-04 A6 = 3.45590E-06 A8 = -3.41508E-08
A10= 1.41269E-10 A12= 0.00000E+00
3rd surface K=-0.3061
A4 = 5.48726E-04 A6 = -5.11105E-06 A8 = -4.02571E-10
A10= 6.06422E-11 A12= 0.00000E+00
4th surface K=-3.9720
A4 = 1.64809E-04 A6 = -6.23672E-07 A8 = -3.44304E-09
A10= 4.26001E-12 A12= 0.00000E+00
5th surface K = 5.8883
A4 = -5.24409E-05 A6 = 5.07414E-07 A8 = 3.77890E-09
A10 = -1.41672E-11 A12 = 0.00000E+00
6th surface K = 0.4195
A4 = 2.57996E-04 A6 = -1.85757E-06 A8 = 2.18453E-09
A10= 5.57891E-11 A12= 0.00000E+00
7th surface K = 4.9451
A4 = -8.67424E-05 A6 = 9.74736E-07 A8 = 5.79036E-09
A10 = -6.53413E-11 A12 = 0.00000E+00
8th surface K = 5.7525
A4 = -2.08333E-04 A6 = 2.55741E-06 A8 = -6.33475E-09
A10 = -2.34517E-11 A12 = 0.00000E+00
この接眼光学系EL2において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表7に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL2, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 7 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表7)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.80 8.77 6.74
D2 20.60 19.63 21.66
EnP -34.92593 -37.22500 -32.79600
(Table 7)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.80 8.77 6.74
D2 20.60 19.63 21.66
EnP -34.92593 -37.22500 -32.79600
次の表8に、この接眼光学系EL2の各条件式対応値を示す。 Table 8 below shows values corresponding to each conditional expression of the eyepiece optical system EL2.
(表8)
f4 =162.068
f12= 33.567
f23=-93.824
[条件式対応値]
(1)fe/f1=1.557
(2)fe/f12=0.540
(3)νd2=23.89
(4)fe/f4=0.112
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.485
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.390
(7)fe/EnP=-0.519
(8)fe/f23=-0.193
(9)D1/f1=0.670
(10)TL/fe=1.550
(11)nd1=1.531
(12)nd2=1.636
(Table 8)
f4 = 162.068
f12 = 33.567
f23=-93.824
[Value corresponding to conditional expression]
(1) fe/f1 = 1.557
(2) fe/f12 = 0.540
(3) νd2 = 23.89
(4) fe/f4 = 0.112
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.485
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.390
(7) fe/EnP = -0.519
(8) fe/f23=-0.193
(9) D1/f1 = 0.670
(10) TL/f = 1.550
(11) nd1 = 1.531
(12) nd2 = 1.636
このように、この接眼光学系EL2は、上記条件式(1)~(4)、(6)~(10)を満足している。 Thus, the eyepiece optical system EL2 satisfies the conditional expressions (1) to (4) and (6) to (10).
この接眼光学系EL2の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図4に示す。これらの各収差図より、この接眼光学系EL2は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 4 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (−1 dpt) of this eyepiece optical system EL2. From these aberration diagrams, it can be seen that the eyepiece optical system EL2 achieves good aberrations within the diopter adjustment range.
[第3実施例]
図5は、第3実施例に係る接眼光学系EL3の構成を示す図である。この接眼光学系EL3は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Third embodiment]
FIG. 5 is a diagram showing the configuration of the eyepiece optical system EL3 according to the third embodiment. The eyepiece optical system EL3 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL3において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面が非球面形状に形成された両凹負レンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、アイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL3, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of a biconcave negative aspherical lens L12 having an aspherical lens surface on the observation object side. The third lens component G3 is composed of a biconvex positive aspherical lens L31 having an aspherical lens surface on the eye point side. The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL3における視度調整は、接眼光学系EL3全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL3 is performed by moving the entire eyepiece optical system EL3 in the optical axis direction.
以下の表9に、接眼光学系EL3の諸元の値を掲げる。 Table 9 below lists the values of the specifications of the eyepiece optical system EL3.
(表9)第3実施例
[全体諸元]
fe = 17.654
H = 6.30
TL = 29.118
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 37.20780 7.34 1.82098 42.50
2* -10.78310 2.69
3* -6.86450 1.58 1.63550 23.89
4 403.03380 0.98
5 365.51190 5.94 1.53110 55.91
6* -10.45160 0.50
7* -40.06410 2.69 1.53110 55.91
8* -25.10660 D2
像面 ∞
(Table 9) Third embodiment [overall specifications]
fe = 17.654
H = 6.30
TL = 29.118
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 37.20780 7.34 1.82098 42.50
2* -10.78310 2.69
3* -6.86450 1.58 1.63550 23.89
4 403.03380 0.98
5 365.51190 5.94 1.53110 55.91
6* -10.45160 0.50
7* -40.06410 2.69 1.53110 55.91
8* -25.10660 D2
Image plane ∞
この接眼光学系EL3において、第1面、第2面、第3面、第6面、第7面及び第8面は非球面形状に形成されている。次の表10に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL3, the first, second, third, sixth, seventh, and eighth surfaces are aspherical. Table 10 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表10)
[非球面データ]
第1面
K= 3.5010
A4 =-1.08770E-04 A6 =-7.76264E-07 A8 = 1.84546E-08
A10=-1.13779E-10 A12= 3.71750E-13
第2面
K=-2.3099
A4 =-1.29893E-04 A6 =9.59335E-07 A8 =-7.24273E-09
A10= 3.52620E-11 A12= 0.00000E+00
第3面
K=-0.1511
A4 = 4.02440E-04 A6 =-4.00609E-06 A8 = 2.11556E-08
A10=-1.51294E-10 A12= 0.00000E+00
第6面
K= 0.5856
A4 = 2.62266E-04 A6 =-6.94589E-07 A8 =-3.75126E-09
A10= 2.70416E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.21897E-04 A6 = 1.25808E-06 A8 =-5.29696E-09
A10= 4.01375E-11 A12= 0.00000E+00
第8面
K= 0.9506
A4 =-2.35090E-04 A6 = 2.42051E-06 A8 =-1.44574E-08
A10= 7.36171E-11 A12= 0.00000E+00
(Table 10)
[Aspheric data]
1st surface K = 3.5010
A4 = -1.08770E-04 A6 = -7.76264E-07 A8 = 1.84546E-08
A10 = -1.13779E-10 A12 = 3.71750E-13
2nd surface K=-2.3099
A4 = -1.29893E-04 A6 = 9.59335E-07 A8 = -7.24273E-09
A10= 3.52620E-11 A12= 0.00000E+00
3rd surface K=-0.1511
A4 = 4.02440E-04 A6 = -4.00609E-06 A8 = 2.11556E-08
A10 = -1.51294E-10 A12 = 0.00000E+00
6th surface K = 0.5856
A4 = 2.62266E-04 A6 = -6.94589E-07 A8 = -3.75126E-09
A10= 2.70416E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.21897E-04 A6 = 1.25808E-06 A8 = -5.29696E-09
A10= 4.01375E-11 A12= 0.00000E+00
8th surface K = 0.9506
A4 = -2.35090E-04 A6 = 2.42051E-06 A8 = -1.44574E-08
A10= 7.36171E-11 A12= 0.00000E+00
この接眼光学系EL3において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表11に、視度毎の可変間隔及び入射瞳位置を示す。 In the eyepiece optical system EL3, the axial air gap D1 between the observation object and the first lens component G1 and the axial air gap D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 11 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表11)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.41 8.34 6.40
D2 20.60 19.67 21.61
EnP -30.17343 -31.78442 -28.65171
(Table 11)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.41 8.34 6.40
D2 20.60 19.67 21.61
EnP -30.17343 -31.78442 -28.65171
次の表12に、この接眼光学系EL3の各条件式対応値を示す。 Table 12 below shows values corresponding to each conditional expression of the eyepiece optical system EL3.
(表12)
f4 =119.198
f12= 34.675
f23=-70.015
[条件式対応値]
(1)fe/f1=1.614
(2)fe/f12=0.509
(3)νd2=23.89
(4)fe/f4=0.148
(5)(G2R2-G3R1)/(G2R2+G3R1)= 0.049
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.551
(7)fe/EnP=-0.585
(8)fe/f23=-0.252
(9)D1/f1=0.678
(10)TL/fe=1.649
(11)nd1=1.821
(12)nd2=1.636
(Table 12)
f4 = 119.198
f12 = 34.675
f23=-70.015
[Value corresponding to conditional expression]
(1) fe/f1 = 1.614
(2) fe/f12 = 0.509
(3) νd2 = 23.89
(4) fe/f4 = 0.148
(5) (G2R2-G3R1)/(G2R2+G3R1) = 0.049
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.551
(7) fe/EnP = -0.585
(8) fe/f23=-0.252
(9) D1/f1 = 0.678
(10) TL/f = 1.649
(11) nd1 = 1.821
(12) nd2 = 1.636
このように、この接眼光学系EL3は、上記条件式(1)~(11)を満足している。 Thus, the eyepiece optical system EL3 satisfies the conditional expressions (1) to (11).
この接眼光学系EL3の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図6に示す。これらの各収差図より、この接眼光学系EL3は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 6 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (-1 dpt) of this eyepiece optical system EL3. From these aberration diagrams, it can be seen that the ocular optical system EL3 achieves good aberrations within the diopter adjustment range.
[第4実施例]
図7は、第4実施例に係る接眼光学系EL4の構成を示す図である。この接眼光学系EL4は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Fourth embodiment]
FIG. 7 is a diagram showing the configuration of the eyepiece optical system EL4 according to the fourth embodiment. The eyepiece optical system EL4 comprises, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL4において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL4, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with a concave surface facing the observation object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. It is The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens whose concave surface faces the observation object and whose lens surface on the observation object side and the lens surface on the eye point side are formed in an aspherical shape. It is The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL4における視度調整は、接眼光学系EL4全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL4 is performed by moving the entire eyepiece optical system EL4 in the optical axis direction.
以下の表13に、接眼光学系EL4の諸元の値を掲げる。 Table 13 below lists the values of the specifications of the eyepiece optical system EL4.
(表13)第4実施例
[全体諸元]
fe = 17.636
H = 6.30
TL = 29.262
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 24.08699 7.78 1.77377 47.25
2* -11.23946 2.66
3* -6.16897 1.50 1.63550 23.89
4* -35.90996 1.64
5* -30.97534 4.55 1.53110 55.91
6* -9.95862 0.50
7* -2317.28230 2.89 1.53110 55.91
8* -41.10583 D2
像面 ∞
(Table 13) Fourth embodiment [overall specifications]
fe = 17.636
H = 6.30
TL = 29.262
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 24.08699 7.78 1.77377 47.25
2* -11.23946 2.66
3* -6.16897 1.50 1.63550 23.89
4* -35.90996 1.64
5* -30.97534 4.55 1.53110 55.91
6* -9.95862 0.50
7* -2317.28230 2.89 1.53110 55.91
8* -41.10583 D2
Image plane ∞
この接眼光学系EL4において、第1面、第2面、第3面、第4面、第5面、第6面、第7面及び第8面は非球面形状に形成されている。次の表14に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL4, the first, second, third, fourth, fifth, sixth, seventh and eighth surfaces are aspherical. Table 14 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表14)
[非球面データ]
第1面
K= 2.7110
A4 =-1.01182E-04 A6 =-1.33523E-06 A8 = 1.97743E-08
A10=-1.25195E-10 A12= 4.06080E-13
第2面
K=-2.9040
A4 =-1.58180E-04 A6 = 1.29335E-06 A8 =-1.01444E-08
A10= 4.38226E-11 A12= 0.00000E+00
第3面
K=-0.4456
A4 = 4.04109E-04 A6 =-4.62087E-06 A8 = 2.20818E-08
A10=-6.21510E-11 A12= 0.00000E+00
第4面
K=-3.9080
A4 = 1.79698E-04 A6 =-1.03102E-06 A8 =-1.74072E-09
A10= 1.01196E-11 A12= 0.00000E+00
第5面
K= 3.7707
A4 =-3.78236E-06 A6 = 1.16143E-06 A8 =-5.58959E-09
A10= 1.44702E-12 A12= 0.00000E+00
第6面
K= 0.6581
A4 = 2.55240E-04 A6 =-5.27043E-07 A8 =-3.06199E-10
A10= 4.00895E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.20441E-04 A6 = 1.18792E-06 A8 =-6.17544E-09
A10= 2.72498E-11 A12= 0.00000E+00
第8面
K=-2.5146
A4 =-2.41805E-04 A6 = 2.45866E-06 A8 =-1.44853E-08
A10= 5.06379E-11 A12= 0.00000E+00
(Table 14)
[Aspheric data]
1st surface K = 2.7110
A4 = -1.01182E-04 A6 = -1.33523E-06 A8 = 1.97743E-08
A10 = -1.25195E-10 A12 = 4.06080E-13
2nd surface K=-2.9040
A4 = -1.58180E-04 A6 = 1.29335E-06 A8 = -1.01444E-08
A10= 4.38226E-11 A12= 0.00000E+00
3rd surface K=-0.4456
A4 = 4.04109E-04 A6 = -4.62087E-06 A8 = 2.20818E-08
A10=-6.21510E-11 A12= 0.00000E+00
4th surface K=-3.9080
A4 = 1.79698E-04 A6 = -1.03102E-06 A8 = -1.74072E-09
A10= 1.01196E-11 A12= 0.00000E+00
5th surface K = 3.7707
A4 = -3.78236E-06 A6 = 1.16143E-06 A8 = -5.58959E-09
A10= 1.44702E-12 A12= 0.00000E+00
6th surface K = 0.6581
A4 = 2.55240E-04 A6 = -5.27043E-07 A8 = -3.06199E-10
A10= 4.00895E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.20441E-04 A6 = 1.18792E-06 A8 = -6.17544E-09
A10= 2.72498E-11 A12= 0.00000E+00
8th surface K=-2.5146
A4 = -2.41805E-04 A6 = 2.45866E-06 A8 = -1.44853E-08
A10= 5.06379E-11 A12= 0.00000E+00
この接眼光学系EL4において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表15に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL4, the axial air gap D1 between the observation object and the first lens component G1 and the axial air gap D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 15 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表15)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.75 8.68 6.74
D2 20.60 19.67 21.61
EnP -28.77738 -30.14404 -27.47277
(Table 15)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.75 8.68 6.74
D2 20.60 19.67 21.61
EnP -28.77738 -30.14404 -27.47277
次の表16に、この接眼光学系EL4の各条件式対応値を示す。 Table 16 below shows values corresponding to each conditional expression of the eyepiece optical system EL4.
(表16)
f4 = 78.761
f12= 26.175
f23=-44.512
[条件式対応値]
(1)fe/f1=1.610
(2)fe/f12=0.674
(3)νd2=23.89
(4)fe/f4=0.224
(5)(G2R2-G3R1)/(G2R2+G3R1)= 0.074
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.364
(7)fe/EnP=-0.613
(8)fe/f23=-0.396
(9)D1/f1=0.707
(10)TL/fe=1.659
(11)nd1=1.774
(12)nd2=1.636
(Table 16)
f4 = 78.761
f12 = 26.175
f23=-44.512
[Value corresponding to conditional expression]
(1) fe/f1 = 1.610
(2) fe/f12 = 0.674
(3) νd2 = 23.89
(4) fe/f4 = 0.224
(5) (G2R2-G3R1)/(G2R2+G3R1) = 0.074
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.364
(7) fe/EnP = -0.613
(8) fe/f23=-0.396
(9) D1/f1 = 0.707
(10) TL/f = 1.659
(11) nd1 = 1.774
(12) nd2 = 1.636
このように、この接眼光学系EL4は、上記条件式(1)~(11)を満足している。 Thus, the eyepiece optical system EL4 satisfies the conditional expressions (1) to (11).
この接眼光学系EL4の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図8に示す。これらの各収差図より、この接眼光学系EL4は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 8 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (−1 dpt) of this eyepiece optical system EL4. From these aberration diagrams, it can be seen that the eyepiece optical system EL4 achieves good aberrations within the diopter adjustment range.
[第5実施例]
図9は、第5実施例に係る接眼光学系EL5の構成を示す図である。この接眼光学系EL5は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Fifth embodiment]
FIG. 9 is a diagram showing the configuration of the eyepiece optical system EL5 according to the fifth embodiment. The eyepiece optical system EL5 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL5において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL5, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with a concave surface facing the observation object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. It is The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens whose concave surface faces the observation object and whose lens surface on the observation object side and the lens surface on the eye point side are formed in an aspherical shape. It is The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL5における視度調整は、接眼光学系EL5全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL5 is performed by moving the entire eyepiece optical system EL5 in the optical axis direction.
以下の表17に、接眼光学系EL5の諸元の値を掲げる。 Table 17 below lists the values of the specifications of the eyepiece optical system EL5.
(表17)第5実施例
[全体諸元]
fe = 18.132
H = 6.30
TL = 27.900
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 18.12430 7.15 1.54392 55.90
2* -8.93740 2.70
3* -5.25010 2.10 1.63550 23.89
4* -15.01890 0.55
5* -24.00760 4.55 1.54392 55.90
6* -9.36770 0.55
7* -2317.28230 2.50 1.54392 55.90
8* -51.99250 D2
像面 ∞
(Table 17) Fifth embodiment [overall specifications]
fe = 18.132
H = 6.30
TL = 27.900
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 18.12430 7.15 1.54392 55.90
2* -8.93740 2.70
3* -5.25010 2.10 1.63550 23.89
4* -15.01890 0.55
5* -24.00760 4.55 1.54392 55.90
6* -9.36770 0.55
7* -2317.28230 2.50 1.54392 55.90
8* -51.99250 D2
Image plane ∞
この接眼光学系EL5において、第1面、第2面、第3面、第4面、第5面、第6面、第7面及び第8面は非球面形状に形成されている。次の表18に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL5, the first, second, third, fourth, fifth, sixth, seventh and eighth surfaces are aspherical. Table 18 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表18)
[非球面データ]
第1面
K= 1.5721
A4 =-1.48925E-04 A6 =-2.27684E-06 A8 = 2.76091E-08
A10=-7.95927E-11 A12= 1.93700E-15
第2面
K=-2.1582
A4 =-2.07700E-04 A6 = 1.44079E-06 A8 =-1.32371E-08
A10= 7.80799E-11 A12= 0.00000E+00
第3面
K=-0.3642
A4 = 4.11218E-04 A6 =-4.53688E-06 A8 = 1.52134E-08
A10=-5.51553E-11 A12= 0.00000E+00
第4面
K=-2.1105
A4 = 1.75549E-04 A6 =-6.55035E-07 A8 =-1.17880E-09
A10=-1.10549E-11 A12= 0.00000E+00
第5面
K=-2.6173
A4 = 3.84318E-05 A6 = 5.26426E-07 A8 =-3.63630E-09
A10= 1.31408E-11 A12= 0.00000E+00
第6面
K= 0.5270
A4 = 3.06334E-04 A6 =-1.20258E-06 A8 =-2.58312E-09
A10= 7.29168E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.44498E-04 A6 = 6.56846E-07 A8 = 4.58887E-09
A10=-2.74632E-11 A12= 0.00000E+00
第8面
K= 3.4680
A4 =-2.80056E-04 A6 = 2.69450E-06 A8 =-1.10674E-08
A10= 1.88829E-11 A12= 0.00000E+00
(Table 18)
[Aspheric data]
1st surface K = 1.5721
A4 = -1.48925E-04 A6 = -2.27684E-06 A8 = 2.76091E-08
A10 = -7.95927E-11 A12 = 1.93700E-15
2nd surface K=-2.1582
A4 = -2.07700E-04 A6 = 1.44079E-06 A8 = -1.32371E-08
A10= 7.80799E-11 A12= 0.00000E+00
3rd surface K=-0.3642
A4 = 4.11218E-04 A6 = -4.53688E-06 A8 = 1.52134E-08
A10=-5.51553E-11 A12= 0.00000E+00
4th surface K=-2.1105
A4 = 1.75549E-04 A6 = -6.55035E-07 A8 = -1.17880E-09
A10 = -1.10549E-11 A12 = 0.00000E+00
5th surface K=-2.6173
A4 = 3.84318E-05 A6 = 5.26426E-07 A8 = -3.63630E-09
A10= 1.31408E-11 A12= 0.00000E+00
6th surface K = 0.5270
A4 = 3.06334E-04 A6 = -1.20258E-06 A8 = -2.58312E-09
A10= 7.29168E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.44498E-04 A6 = 6.56846E-07 A8 = 4.58887E-09
A10 = -2.74632E-11 A12 = 0.00000E+00
8th surface K = 3.4680
A4 = -2.80056E-04 A6 = 2.69450E-06 A8 = -1.10674E-08
A10= 1.88829E-11 A12= 0.00000E+00
この接眼光学系EL5において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表19に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL5, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 19 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表19)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.80 8.78 6.74
D2 20.70 19.72 21.76
EnP -34.42818 -36.66472 -32.37294
(Table 19)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.80 8.78 6.74
D2 20.70 19.72 21.76
EnP -34.42818 -36.66472 -32.37294
次の表20に、この接眼光学系EL5の各条件式対応値を示す。 Table 20 below shows values corresponding to each conditional expression of the eyepiece optical system EL5.
(表20)
f4 = 97.744
f12= 31.386
f23=-77.761
[条件式対応値]
(1)fe/f1=1.494
(2)fe/f12=0.578
(3)νd2=23.89
(4)fe/f4=0.186
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.230
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.339
(7)fe/EnP=-0.527
(8)fe/f23=-0.233
(9)D1/f1=0.643
(10)TL/fe=1.539
(11)nd1=1.544
(12)nd2=1.636
(Table 20)
f4 = 97.744
f12 = 31.386
f23=-77.761
[Value corresponding to conditional expression]
(1) fe/f1 = 1.494
(2) fe/f12 = 0.578
(3) νd2 = 23.89
(4) fe/f4 = 0.186
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.230
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.339
(7) fe/EnP = -0.527
(8) fe/f23=-0.233
(9) D1/f1 = 0.643
(10) TL/f = 1.539
(11) nd1 = 1.544
(12) nd2 = 1.636
このように、この接眼光学系EL5は、上記条件式(1)~(10)を満足している。 Thus, the eyepiece optical system EL5 satisfies the conditional expressions (1) to (10).
この接眼光学系EL5の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図10に示す。これらの各収差図より、この接眼光学系EL5は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 10 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (-1 dpt) of this eyepiece optical system EL5. From these aberration diagrams, it can be seen that the ocular optical system EL5 achieves good aberrations within the diopter adjustment range.
[第6実施例]
図11は、第6実施例に係る接眼光学系EL6の構成を示す図である。この接眼光学系EL6は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Sixth embodiment]
FIG. 11 is a diagram showing the configuration of the eyepiece optical system EL6 according to the sixth embodiment. The eyepiece optical system EL6 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL6において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL6, the first lens component G1 is composed of a double-convex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with a concave surface facing the observation object side, the lens surface on the observation object side and the lens surface on the eyepoint side being aspherical. It is The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens whose concave surface faces the observation object and whose lens surface on the observation object side and the lens surface on the eye point side are formed in an aspherical shape. It is The fourth lens component G4 is composed of a biconvex positive aspherical lens L41 in which the lens surface on the observation object side and the lens surface on the eye point side are formed in aspherical shapes.
この接眼光学系EL6における視度調整は、接眼光学系EL6全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL6 is performed by moving the entire eyepiece optical system EL6 in the optical axis direction.
以下の表21に、接眼光学系EL6の諸元の値を掲げる。 Table 21 below lists the values of the specifications of the eyepiece optical system EL6.
(表21)第6実施例
[全体諸元]
fe = 18.123
H = 6.30
TL = 28.139
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 16.56700 7.54 1.53110 55.91
2* -8.36450 2.40
3* -5.15230 2.11 1.63550 23.89
4* -15.20140 0.72
5* -23.94520 4.46 1.53110 55.91
6* -9.83340 0.50
7* 153.86920 2.57 1.53110 55.91
8* -57.12010 D2
像面 ∞
(Table 21) Sixth embodiment [overall specifications]
fe = 18.123
H = 6.30
TL = 28.139
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 16.56700 7.54 1.53110 55.91
2* -8.36450 2.40
3* -5.15230 2.11 1.63550 23.89
4* -15.20140 0.72
5* -23.94520 4.46 1.53110 55.91
6* -9.83340 0.50
7* 153.86920 2.57 1.53110 55.91
8* -57.12010 D2
Image plane ∞
この接眼光学系EL6において、第1面、第2面、第3面、第4面、第5面、第6面、第7面及び第8面は非球面形状に形成されている。次の表22に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL6, the first, second, third, fourth, fifth, sixth, seventh and eighth surfaces are aspherical. Table 22 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表22)
[非球面データ]
第1面
K= 0.7228
A4 =-1.63997E-04 A6 =-2.61921E-06 A8 = 3.31813E-08
A10=-1.23005E-10 A12= 1.44200E-13
第2面
K=-2.0402
A4 =-2.39241E-04 A6 = 1.88690E-06 A8 =-1.74329E-08
A10= 7.72117E-11 A12= 0.00000E+00
第3面
K=-0.4513
A4 = 4.08176E-04 A6 =-4.24658E-06 A8 = 1.05383E-08
A10=-4.81073E-11 A12= 0.00000E+00
第4面
K=-2.0834
A4 = 1.95661E-04 A6 =-5.64298E-07 A8 =-2.58247E-09
A10=-1.66041E-11 A12= 0.00000E+00
第5面
K=-3.9899
A4 = 7.61468E-06 A6 = 4.89100E-07 A8 = 5.08311E-10
A10=-5.69059E-12 A12= 0.00000E+00
第6面
K= 0.4497
A4 = 2.70507E-04 A6 =-1.61737E-06 A8 =-1.10795E-09
A10= 7.33076E-11 A12= 0.00000E+00
第7面
K=-4.0000
A4 =-1.50783E-04 A6 = 6.32142E-07 A8 = 8.23469E-09
A10=-5.41717E-11 A12= 0.00000E+00
第8面
K= 4.7540
A4 =-2.61403E-04 A6 = 2.68176E-06 A8 =-9.54981E-09
A10= 4.35054E-12 A12= 0.00000E+00
(Table 22)
[Aspheric data]
1st surface K = 0.7228
A4 = -1.63997E-04 A6 = -2.61921E-06 A8 = 3.31813E-08
A10 = -1.23005E-10 A12 = 1.44200E-13
2nd surface K=-2.0402
A4 = -2.39241E-04 A6 = 1.88690E-06 A8 = -1.74329E-08
A10= 7.72117E-11 A12= 0.00000E+00
3rd surface K=-0.4513
A4 = 4.08176E-04 A6 = -4.24658E-06 A8 = 1.05383E-08
A10=-4.81073E-11 A12= 0.00000E+00
4th surface K=-2.0834
A4 = 1.95661E-04 A6 = -5.64298E-07 A8 = -2.58247E-09
A10 = -1.66041E-11 A12 = 0.00000E+00
5th surface K=-3.9899
A4 = 7.61468E-06 A6 = 4.89100E-07 A8 = 5.08311E-10
A10 = -5.69059E-12 A12 = 0.00000E+00
6th surface K = 0.4497
A4 = 2.70507E-04 A6 = -1.61737E-06 A8 = -1.10795E-09
A10= 7.33076E-11 A12= 0.00000E+00
7th surface K=-4.0000
A4 = -1.50783E-04 A6 = 6.32142E-07 A8 = 8.23469E-09
A10=-5.41717E-11 A12= 0.00000E+00
8th surface K = 4.7540
A4 = -2.61403E-04 A6 = 2.68176E-06 A8 = -9.54981E-09
A10= 4.35054E-12 A12= 0.00000E+00
この接眼光学系EL6において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表23に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL6, the axial air gap D1 between the observation object and the first lens component G1 and the axial air gap D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 23 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表23)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.84 8.82 6.78
D2 20.60 19.62 21.66
EnP -34.03960 -36.20254 -32.04697
(Table 23)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.84 8.82 6.78
D2 20.60 19.62 21.66
EnP -34.03960 -36.20254 -32.04697
次の表24に、この接眼光学系EL6の各条件式対応値を示す。 Table 24 below shows values corresponding to each conditional expression of the eyepiece optical system EL6.
(表24)
f4 = 78.767
f12= 30.113
f23=-49.345
[条件式対応値]
(1)fe/f1=1.550
(2)fe/f12=0.602
(3)νd2=23.89
(4)fe/f4=0.230
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.223
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.329
(7)fe/EnP=-0.532
(8)fe/f23=-0.367
(9)D1/f1=0.671
(10)TL/fe=1.553
(11)nd1=1.531
(12)nd2=1.636
(Table 24)
f4 = 78.767
f12 = 30.113
f23=-49.345
[Value corresponding to conditional expression]
(1) fe/f1 = 1.550
(2) fe/f12 = 0.602
(3) νd2 = 23.89
(4) fe/f4 = 0.230
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.223
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.329
(7) fe/EnP = -0.532
(8) fe/f23=-0.367
(9) D1/f1 = 0.671
(10) TL/fe = 1.553
(11) nd1 = 1.531
(12) nd2 = 1.636
このように、この接眼光学系EL6は、上記条件式(1)~(10)を満足している。 Thus, the eyepiece optical system EL6 satisfies the conditional expressions (1) to (10).
この接眼光学系EL6の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図12に示す。これらの各収差図より、この接眼光学系EL6は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 12 shows a spherical aberration diagram, an astigmatism diagram, a distortion diagram, and a coma aberration diagram at the reference diopter (−1 dpt) of this eyepiece optical system EL6. From these aberration diagrams, it can be seen that the eyepiece optical system EL6 achieves good aberrations within the diopter adjustment range.
[第7実施例]
図13は、第7実施例に係る接眼光学系EL7の構成を示す図である。この接眼光学系EL7は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Seventh embodiment]
FIG. 13 is a diagram showing the configuration of the eyepiece optical system EL7 according to the seventh embodiment. The eyepiece optical system EL7 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL7において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、アイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL7, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with an aspherical lens surface on the observation object side and a concave surface facing the observation object side. The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens having an aspherical lens surface on the eyepoint side and a concave surface facing the observation object side. The fourth lens component G4 is composed of a biconvex positive aspherical lens L41 in which the lens surface on the observation object side and the lens surface on the eye point side are formed in aspherical shapes.
この接眼光学系EL7における視度調整は、接眼光学系EL7全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL7 is performed by moving the entire eyepiece optical system EL7 in the optical axis direction.
以下の表25に、接眼光学系EL7の諸元の値を掲げる。 Table 25 below lists the values of the specifications of the eyepiece optical system EL7.
(表25)第7実施例
[全体諸元]
fe = 17.662
H = 6.30
TL = 28.320
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 28.07266 7.30 1.74400 44.80
2* -10.67758 2.70
3* -6.63855 1.55 1.63550 23.89
4 -144.14719 1.00
5 -167.66045 5.95 1.53110 55.91
6* -11.29042 0.50
7* 1712.67070 2.70 1.53110 55.91
8* -31.84183 D2
像面 ∞
(Table 25) Seventh embodiment [overall specifications]
fe = 17.662
H = 6.30
TL = 28.320
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 28.07266 7.30 1.74400 44.80
2* -10.67758 2.70
3* -6.63855 1.55 1.63550 23.89
4 -144.14719 1.00
5 -167.66045 5.95 1.53110 55.91
6* -11.29042 0.50
7* 1712.67070 2.70 1.53110 55.91
8* -31.84183 D2
Image plane ∞
この接眼光学系EL7において、第1面、第2面、第3面、第6面、第7面及び第8面は非球面形状に形成されている。次の表26に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL7, the first, second, third, sixth, seventh and eighth surfaces are aspherical. The following Table 26 shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表26)
[非球面データ]
第1面
K=-2.0140
A4 =-1.26801E-04 A6 =-7.92018E-07 A8 = 1.72033E-08
A10=-1.32394E-10 A12= 5.48090E-13
第2面
K=-2.1884
A4 =-1.51405E-04 A6 = 8.63584E-07 A8 =-7.98722E-09
A10= 2.78537E-11 A12= 0.00000E+00
第3面
K=-0.1010
A4 = 3.80395E-04 A6 =-4.01258E-06 A8 = 2.22431E-08
A10=-1.81820E-10 A12= 0.00000E+00
第6面
K= 0.6429
A4 = 2.44680E-04 A6 =-7.34170E-07 A8 =-4.17875E-09
A10= 2.11837E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.23377E-04 A6 = 1.23089E-06 A8 =-5.34263E-09
A10= 3.90858E-11 A12= 0.00000E+00
第8面
K=-0.0905
A4 =-2.34359E-04 A6 = 2.48218E-06 A8 =-1.41661E-08
A10= 7.75465E-11 A12= 0.00000E+00
(Table 26)
[Aspheric data]
1st surface K=-2.0140
A4 = -1.26801E-04 A6 = -7.92018E-07 A8 = 1.72033E-08
A10 = -1.32394E-10 A12 = 5.48090E-13
2nd surface K=-2.1884
A4 = -1.51405E-04 A6 = 8.63584E-07 A8 = -7.98722E-09
A10= 2.78537E-11 A12= 0.00000E+00
3rd surface K=-0.1010
A4 = 3.80395E-04 A6 = -4.01258E-06 A8 = 2.22431E-08
A10=-1.81820E-10 A12= 0.00000E+00
6th surface K = 0.6429
A4 = 2.44680E-04 A6 = -7.34170E-07 A8 = -4.17875E-09
A10= 2.11837E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.23377E-04 A6 = 1.23089E-06 A8 = -5.34263E-09
A10= 3.90858E-11 A12= 0.00000E+00
8th surface K=-0.0905
A4 = -2.34359E-04 A6 = 2.48218E-06 A8 = -1.41661E-08
A10= 7.75465E-11 A12= 0.00000E+00
この接眼光学系EL7において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表27に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL7, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 27 below shows the variable spacing and entrance pupil positions for each diopter.
(表27)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 6.62 7.55 5.61
D2 20.10 19.17 21.11
EnP -30.15672 -31.88364 -28.53315
(Table 27)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 6.62 7.55 5.61
D2 20.10 19.17 21.11
EnP -30.15672 -31.88364 -28.53315
次の表28に、この接眼光学系EL7の各条件式対応値を示す。 Table 28 below shows values corresponding to each conditional expression of the eyepiece optical system EL7.
(表28)
f4 = 58.892
f12= 34.529
f23=-45.926
[条件式対応値]
(1)fe/f1=1.562
(2)fe/f12=0.512
(3)νd2=23.89
(4)fe/f4=0.300
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.075
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.449
(7)fe/EnP=-0.586
(8)fe/f23=-0.385
(9)D1/f1=0.586
(10)TL/fe=1.603
(11)nd1=1.744
(12)nd2=1.636
(Table 28)
f4 = 58.892
f12 = 34.529
f23=-45.926
[Value corresponding to conditional expression]
(1) fe/f1 = 1.562
(2) fe/f12 = 0.512
(3) νd2 = 23.89
(4) fe/f4 = 0.300
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.075
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.449
(7) fe/EnP = -0.586
(8) fe/f23=-0.385
(9) D1/f1 = 0.586
(10) TL/fe = 1.603
(11) nd1 = 1.744
(12) nd2 = 1.636
このように、この接眼光学系EL7は、上記条件式(1)~(11)を満足している。 Thus, the eyepiece optical system EL7 satisfies the conditional expressions (1) to (11).
この接眼光学系EL7の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図14に示す。これらの各収差図より、この接眼光学系EL7は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 14 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (−1 dpt) of this eyepiece optical system EL7. From these aberration diagrams, it can be seen that the eyepiece optical system EL7 achieves good aberrations within the diopter adjustment range.
[第8実施例]
図15は、第8実施例に係る接眼光学系EL8の構成を示す図である。この接眼光学系EL8は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Eighth embodiment]
FIG. 15 is a diagram showing the configuration of an eyepiece optical system EL8 according to the eighth embodiment. The eyepiece optical system EL8 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL8において、第1レンズ成分G1は、観察物体側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11とアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL12とを接合した接合レンズで構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、アイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL8, the first lens component G1 includes a biconvex positive aspherical lens L11 having an aspherical lens surface on the observation object side and an aspherical lens surface on the eye point side. , and is composed of a cemented lens that is cemented with an aspherical positive lens L12 having a positive meniscus lens shape with a concave surface facing the observation object side. The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with an aspherical lens surface on the observation object side and a concave surface facing the observation object side. The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens having an aspherical lens surface on the eyepoint side and a concave surface facing the observation object side. The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL8における視度調整は、接眼光学系EL8全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL8 is performed by moving the entire eyepiece optical system EL8 in the optical axis direction.
以下の表29に、接眼光学系EL8の諸元の値を掲げる。 Table 29 below lists the values of the specifications of the eyepiece optical system EL8.
(表29)第8実施例
[全体諸元]
fe = 17.671
H = 6.30
TL = 28.340
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 36.28535 1.50 1.75520 27.57
2 -256.85195 5.55 1.74400 44.80
3* -9.58387 2.70
4* -6.33627 1.60 1.63550 23.89
5 -309.22499 1.00
6 -340.41004 5.95 1.53110 55.91
7* -10.20313 0.50
8* -118.11140 2.70 1.53110 55.91
9* -33.13998 D2
像面 ∞
(Table 29) Eighth embodiment [overall specifications]
fe = 17.671
H = 6.30
TL = 28.340
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 36.28535 1.50 1.75520 27.57
2 -256.85195 5.55 1.74400 44.80
3* -9.58387 2.70
4* -6.33627 1.60 1.63550 23.89
5 -309.22499 1.00
6 -340.41004 5.95 1.53110 55.91
7* -10.20313 0.50
8* -118.11140 2.70 1.53110 55.91
9* -33.13998 D2
Image plane ∞
この接眼光学系EL8において、第1面、第3面、第4面、第7面、第8面及び第9面は非球面形状に形成されている。次の表30に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL8, the first, third, fourth, seventh, eighth, and ninth surfaces are aspherical. Table 30 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表30)
[非球面データ]
第1面
K=-2.0658
A4 =-1.42501E-04 A6 =-8.76658E-07 A8 = 1.88394E-08
A10=-1.09268E-10 A12= 3.68460E-13
第3面
K=-1.7532
A4 =-1.52859E-04 A6 = 8.23715E-07 A8 =-8.45101E-09
A10= 3.67563E-11 A12= 0.00000E+00
第4面
K=-0.2498
A4 = 3.64026E-04 A6 =-4.01765E-06 A8 = 2.07275E-08
A10=-1.61058E-10 A12= 0.00000E+00
第7面
K= 0.5740
A4 = 2.54149E-04 A6 =-6.32718E-07 A8 =-3.76424E-09
A10= 2.73994E-11 A12= 0.00000E+00
第8面
K= 1.0000
A4 =-1.19587E-04 A6 = 1.18521E-06 A8 =-5.01478E-09
A10= 4.10280E-11 A12= 0.00000E+00
第9面
K= 1.4393
A4 =-2.39375E-04 A6 = 2.51700E-06 A8 =-1.48286E-08
A10= 7.54336E-11 A12= 0.00000E+00
(Table 30)
[Aspheric data]
1st surface K=-2.0658
A4 = -1.42501E-04 A6 = -8.76658E-07 A8 = 1.88394E-08
A10 = -1.09268E-10 A12 = 3.68460E-13
3rd surface K=-1.7532
A4 = -1.52859E-04 A6 = 8.23715E-07 A8 = -8.45101E-09
A10= 3.67563E-11 A12= 0.00000E+00
4th surface K=-0.2498
A4 = 3.64026E-04 A6 = -4.01765E-06 A8 = 2.07275E-08
A10 = -1.61058E-10 A12 = 0.00000E+00
7th surface K = 0.5740
A4 = 2.54149E-04 A6 = -6.32718E-07 A8 = -3.76424E-09
A10= 2.73994E-11 A12= 0.00000E+00
8th surface K= 1.0000
A4 = -1.19587E-04 A6 = 1.18521E-06 A8 = -5.01478E-09
A10= 4.10280E-11 A12= 0.00000E+00
9th surface K = 1.4393
A4 = -2.39375E-04 A6 = 2.51700E-06 A8 = -1.48286E-08
A10= 7.54336E-11 A12= 0.00000E+00
この接眼光学系EL8において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表31に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL8, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 31 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表31)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 6.84 7.77 5.83
D2 20.10 19.17 21.11
EnP -31.23485 -33.09550 -29.49620
(Table 31)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 6.84 7.77 5.83
D2 20.10 19.17 21.11
EnP -31.23485 -33.09550 -29.49620
次の表32に、この接眼光学系EL8の各条件式対応値を示す。 Table 32 below shows values corresponding to each conditional expression of the eyepiece optical system EL8.
(表32)
f4 = 85.790
f12= 37.994
f23=-57.363
[条件式対応値]
(1)fe/f1=1.625
(2)fe/f12=0.465
(3)νd2=23.89
(4)fe/f4=0.206
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.048
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.582
(7)fe/EnP=-0.566
(8)fe/f23=-0.308
(9)D1/f1=0.629
(10)TL/fe=1.604
(11)nd1=1.755
(12)nd2=1.636
(Table 32)
f4 = 85.790
f12 = 37.994
f23=-57.363
[Value corresponding to conditional expression]
(1) fe/f1 = 1.625
(2) fe/f12 = 0.465
(3) νd2 = 23.89
(4) fe/f4 = 0.206
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.048
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.582
(7) fe/EnP = -0.566
(8) fe/f23=-0.308
(9) D1/f1 = 0.629
(10) TL/fe = 1.604
(11) nd1 = 1.755
(12) nd2 = 1.636
このように、この接眼光学系EL8は、上記条件式(1)~(11)を満足している。 Thus, the eyepiece optical system EL8 satisfies the conditional expressions (1) to (11).
この接眼光学系EL8の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図16に示す。これらの各収差図より、この接眼光学系EL8は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 16 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (-1 dpt) of this eyepiece optical system EL8. From these aberration diagrams, it can be seen that the eyepiece optical system EL8 achieves good aberrations within the diopter adjustment range.
[第9実施例]
図17は、第9実施例に係る接眼光学系EL9の構成を示す図である。この接眼光学系EL9は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Ninth embodiment]
FIG. 17 is a diagram showing the configuration of an eyepiece optical system EL9 according to the ninth embodiment. The eyepiece optical system EL9 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL9において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL12で構成されている。また、第3レンズ成分G3は、アイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL9, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eye point side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L12 having a negative meniscus lens shape with an aspherical lens surface on the observation object side and a concave surface facing the observation object side. The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens having an aspherical lens surface on the eyepoint side and a concave surface facing the observation object side. The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL9における視度調整は、接眼光学系EL9全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL9 is performed by moving the entire eyepiece optical system EL9 in the optical axis direction.
以下の表33に、接眼光学系EL9の諸元の値を掲げる。 Table 33 below lists the values of the specifications of the eyepiece optical system EL9.
(表33)第9実施例
[全体諸元]
fe = 17.664
H = 6.30
TL = 28.440
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 30.06223 7.30 1.74300 49.25
2* -10.46380 2.70
3* -6.62848 1.55 1.65093 21.51
4 -43.12860 1.00
5 -44.49530 5.95 1.53110 55.91
6* -10.78420 0.50
7* -1133.34000 2.70 1.53110 55.91
8* -34.07780 D2
像面 ∞
(Table 33) Ninth embodiment [overall specifications]
fe = 17.664
H = 6.30
TL = 28.440
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 30.06223 7.30 1.74300 49.25
2* -10.46380 2.70
3* -6.62848 1.55 1.65093 21.51
4 -43.12860 1.00
5 -44.49530 5.95 1.53110 55.91
6* -10.78420 0.50
7* -1133.34000 2.70 1.53110 55.91
8* -34.07780 D2
Image plane ∞
この接眼光学系EL9において、第1面、第2面、第3面、第6面、第7面及び第8面は非球面形状に形成されている。次の表34に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In this eyepiece optical system EL9, the first, second, third, sixth, seventh and eighth surfaces are formed in an aspherical shape. Table 34 below shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表34)
[非球面データ]
第1面
K=-1.3191
A4 =-1.08297E-04 A6 =-5.23642E-07 A8 = 1.65142E-08
A10=-1.39777E-10 A12= 5.22770E-13
第2面
K=-2.1775
A4 =-1.37725E-04 A6 = 9.31664E-07 A8 =-7.77285E-09
A10= 2.31975E-11 A12= 0.00000E+00
第3面
K=-0.0873
A4 = 3.71838E-04 A6 =-4.12160E-06 A8 = 2.25930E-08
A10=-1.98410E-10 A12= 0.00000E+00
第6面
K= 0.6318
A4 = 2.37664E-04 A6 =-7.12383E-07 A8 =-4.02440E-09
A10= 2.46401E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.19476E-04 A6 = 1.21154E-06 A8 =-5.10047E-09
A10= 4.12044E-11 A12= 0.00000E+00
第8面
K=-0.6189
A4 =-2.32309E-04 A6 = 2.50741E-06 A8 =-1.40702E-08
A10= 7.88020E-11 A12= 0.00000E+00
(Table 34)
[Aspheric data]
1st surface K=-1.3191
A4 = -1.08297E-04 A6 = -5.23642E-07 A8 = 1.65142E-08
A10 = -1.39777E-10 A12 = 5.22770E-13
2nd surface K=-2.1775
A4 = -1.37725E-04 A6 = 9.31664E-07 A8 = -7.77285E-09
A10= 2.31975E-11 A12= 0.00000E+00
3rd surface K=-0.0873
A4 = 3.71838E-04 A6 = -4.12160E-06 A8 = 2.25930E-08
A10 = -1.98410E-10 A12 = 0.00000E+00
6th surface K = 0.6318
A4 = 2.37664E-04 A6 = -7.12383E-07 A8 = -4.02440E-09
A10= 2.46401E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.19476E-04 A6 = 1.21154E-06 A8 = -5.10047E-09
A10= 4.12044E-11 A12= 0.00000E+00
8th surface K=-0.6189
A4 = -2.32309E-04 A6 = 2.50741E-06 A8 = -1.40702E-08
A10= 7.88020E-11 A12= 0.00000E+00
この接眼光学系EL9において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表35に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL9, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 35 below shows the variable spacing and entrance pupil positions for each dioptric power.
(表35)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 6.74 7.67 5.73
D2 20.00 19.07 20.01
EnP -31.17085 -32.51888 -29.03853
(Table 35)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 6.74 7.67 5.73
D2 20.00 19.07 20.01
EnP -31.17085 -32.51888 -29.03853
次の表36に、この接眼光学系EL9の各条件式対応値を示す。 Table 36 below shows values corresponding to each conditional expression of the eyepiece optical system EL9.
(表36)
f4 = 66.097
f12= 29.977
f23=-51.032
[条件式対応値]
(1)fe/f1=1.561
(2)fe/f12=0.589
(3)νd2=21.51
(4)fe/f4=0.267
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.016
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.484
(7)fe/EnP=-0.567
(8)fe/f23=-0.346
(9)D1/f1=0.596
(10)TL/fe=1.610
(11)nd1=1.743
(12)nd2=1.651
(Table 36)
f4 = 66.097
f12 = 29.977
f23=-51.032
[Value corresponding to conditional expression]
(1) fe/f1 = 1.561
(2) fe/f12 = 0.589
(3) νd2 = 21.51
(4) fe/f4 = 0.267
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.016
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.484
(7) fe/EnP = -0.567
(8) fe/f23=-0.346
(9) D1/f1 = 0.596
(10) TL/f = 1.610
(11) nd1 = 1.743
(12) nd2 = 1.651
このように、この接眼光学系EL9は、上記条件式(1)~(12)を満足している。 Thus, the eyepiece optical system EL9 satisfies the conditional expressions (1) to (12).
この接眼光学系EL9の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図18に示す。これらの各収差図より、この接眼光学系EL9は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 18 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the standard diopter (−1 dpt) of this eyepiece optical system EL9. From these aberration diagrams, it can be seen that the eyepiece optical system EL9 achieves good aberrations within the diopter adjustment range.
[第10実施例]
図19は、第10実施例に係る接眼光学系EL10の構成を示す図である。この接眼光学系EL10は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[Tenth embodiment]
FIG. 19 is a diagram showing the configuration of the eyepiece optical system EL10 according to the tenth embodiment. The eyepiece optical system EL10 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL10において、第1レンズ成分G1は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた負メニスカスレンズ形状の非球面負レンズL21で構成されている。また、第3レンズ成分G3は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL10, the first lens component G1 is composed of a biconvex positive aspherical lens L11 in which the lens surface on the observation object side and the lens surface on the eyepoint side are formed in aspherical shapes. there is The second lens component G2 is composed of an aspherical negative lens L21 having a negative meniscus lens shape with a concave surface facing the observation object side, the lens surface on the observation object side and the lens surface on the eye point side being aspherical. It is The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens whose concave surface faces the observation object and whose lens surface on the observation object side and the lens surface on the eye point side are formed in an aspherical shape. It is The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL10における視度調整は、接眼光学系EL10全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL10 is performed by moving the entire eyepiece optical system EL10 in the optical axis direction.
以下の表37に、接眼光学系EL10の諸元の値を掲げる。 Table 37 below lists the values of the specifications of the eyepiece optical system EL10.
(表37)第10実施例
[全体諸元]
fe = 17.655
H = 6.30
TL = 28.870
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 27.64520 7.35 1.74300 49.25
2* -10.59980 2.70
3* -6.62160 1.50 1.66133 20.35
4* -30.41490 1.00
5* -33.42740 5.95 1.53110 55.91
6* -11.06910 0.50
7* -447.12000 2.70 1.53110 55.91
8* -33.61500 D2
像面 ∞
(Table 37) Tenth embodiment [overall specifications]
fe = 17.655
H = 6.30
TL = 28.870
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 27.64520 7.35 1.74300 49.25
2* -10.59980 2.70
3* -6.62160 1.50 1.66133 20.35
4* -30.41490 1.00
5* -33.42740 5.95 1.53110 55.91
6* -11.06910 0.50
7* -447.12000 2.70 1.53110 55.91
8* -33.61500 D2
Image plane ∞
この接眼光学系EL10において、第1面、第2面、第3面、第4面、第5面、第6面、第7面及び第8面は非球面形状に形成されている。次の表38に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL10, the first, second, third, fourth, fifth, sixth, seventh and eighth surfaces are aspherical. Table 38 below shows the data for the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表38)
[非球面データ]
第1面
K= 1.8706
A4 =-1.58806E-04 A6 =-6.47977E-07 A8 = 2.00513E-08
A10=-1.19924E-10 A12= 3.39780E-13
第2面
K=-2.5122
A4 =-1.82235E-04 A6 = 1.26664E-06 A8 =-9.55146E-09
A10= 4.41287E-11 A12= 0.00000E+00
第3面
K=-0.1010
A4 = 3.59553E-04 A6 =-3.81376E-06 A8 = 2.31702E-08
A10=-1.65901E-10 A12= 0.00000E+00
第4面
K= 1.2085
A4 = 9.08220E-06 A6 = 4.92684E-09 A8 = 2.99069E-11
A10= 0.00000E+00 A12= 0.00000E+00
第5面
K=-0.6362
A4 = 2.08532E-05 A6 = 3.39041E-08 A8 =-4.09295E-10
A10= 0.00000E+00 A12= 0.00000E+00
第6面
K= 0.5759
A4 = 2.44689E-04 A6 =-6.87340E-07 A8 =-4.20734E-09
A10= 2.20759E-11 A12= 0.00000E+00
第7面
K= 1.0000
A4 =-1.28197E-04 A6 = 1.23524E-06 A8 =-5.32987E-09
A10= 3.98596E-11 A12= 0.00000E+00
第8面
K= 0.3803
A4 =-2.29306E-04 A6 = 2.47452E-06 A8 =-1.42769E-08
A10= 7.86334E-11 A12= 0.00000E+00
(Table 38)
[Aspheric data]
1st surface K = 1.8706
A4 = -1.58806E-04 A6 = -6.47977E-07 A8 = 2.00513E-08
A10 = -1.19924E-10 A12 = 3.39780E-13
2nd surface K=-2.5122
A4 = -1.82235E-04 A6 = 1.26664E-06 A8 = -9.55146E-09
A10= 4.41287E-11 A12= 0.00000E+00
3rd surface K=-0.1010
A4 = 3.59553E-04 A6 = -3.81376E-06 A8 = 2.31702E-08
A10 = -1.65901E-10 A12 = 0.00000E+00
4th surface K = 1.2085
A4 = 9.08220E-06 A6 = 4.92684E-09 A8 = 2.99069E-11
A10 = 0.00000E+00 A12 = 0.00000E+00
5th surface K=-0.6362
A4 = 2.08532E-05 A6 = 3.39041E-08 A8 = -4.09295E-10
A10 = 0.00000E+00 A12 = 0.00000E+00
6th surface K = 0.5759
A4 = 2.44689E-04 A6 = -6.87340E-07 A8 = -4.20734E-09
A10= 2.20759E-11 A12= 0.00000E+00
7th surface K = 1.0000
A4 = -1.28197E-04 A6 = 1.23524E-06 A8 = -5.32987E-09
A10= 3.98596E-11 A12= 0.00000E+00
8th surface K= 0.3803
A4 = -2.29306E-04 A6 = 2.47452E-06 A8 = -1.42769E-08
A10= 7.86334E-11 A12= 0.00000E+00
この接眼光学系EL10において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表39に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL10, the axial air gap D1 between the observation object and the first lens component G1 and the axial air gap D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 39 below shows the variable spacing and entrance pupil positions for each diopter.
(表39)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.17 8.10 6.16
D2 20.10 19.17 21.11
EnP -30.13523 -31.77608 -28.58721
(Table 39)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.17 8.10 6.16
D2 20.10 19.17 21.11
EnP -30.13523 -31.77608 -28.58721
次の表40に、この接眼光学系EL10の各条件式対応値を示す。 Table 40 below shows values corresponding to each conditional expression of the eyepiece optical system EL10.
(表40)
f4 = 68.284
f12= 26.280
f23=-47.435
[条件式対応値]
(1)fe/f1=1.572
(2)fe/f12=0.672
(3)νd2=20.35
(4)fe/f4=0.259
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.047
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.446
(7)fe/EnP=-0.586
(8)fe/f23=-0.372
(9)D1/f1=0.638
(10)TL/fe=1.635
(11)nd1=1.743
(12)nd2=1.661
(Table 40)
f4 = 68.284
f12 = 26.280
f23=-47.435
[Value corresponding to conditional expression]
(1) fe/f1 = 1.572
(2) fe/f12 = 0.672
(3) νd2 = 20.35
(4) fe/f4 = 0.259
(5) (G2R2-G3R1)/(G2R2+G3R1)=-0.047
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.446
(7) fe/EnP = -0.586
(8) fe/f23=-0.372
(9) D1/f1 = 0.638
(10) TL/f = 1.635
(11) nd1 = 1.743
(12) nd2 = 1.661
このように、この接眼光学系EL10は、上記条件式(1)~(12)を満足している。 Thus, the eyepiece optical system EL10 satisfies the conditional expressions (1) to (12).
この接眼光学系EL10の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図20に示す。これらの各収差図より、この接眼光学系EL10は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 20 shows a spherical aberration diagram, an astigmatism diagram, a distortion aberration diagram, and a coma aberration diagram at the reference diopter (-1 dpt) of this eyepiece optical system EL10. From these aberration diagrams, it can be seen that the eyepiece optical system EL10 achieves good aberrations within the diopter adjustment range.
[第11実施例]
図21は、第11実施例に係る接眼光学系EL11の構成を示す図である。この接眼光学系EL11は、観察物体側から順に、正の屈折力を有する第1レンズ成分G1と、負の屈折力を有する第2レンズ成分G2と、正の屈折力を有する第3レンズ成分G3と、正の屈折力を有する第4レンズ成分G4と、を有して構成されている。
[11th embodiment]
FIG. 21 is a diagram showing the configuration of an eyepiece optical system EL11 according to the eleventh embodiment. The eyepiece optical system EL11 includes, in order from the observation object side, a first lens component G1 having positive refractive power, a second lens component G2 having negative refractive power, and a third lens component G3 having positive refractive power. and a fourth lens component G4 having a positive refractive power.
この接眼光学系EL11において、第1レンズ成分G1は、観察物体側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL11で構成されている。また、第2レンズ成分G2は、観察物体側のレンズ面が非球面形状に形成された両凹負レンズ形状の非球面負レンズL21とアイポイント側のレンズ面が非球面形状に形成された両凸正レンズ形状の非球面正レンズL22とを接合した接合レンズで構成されている。また、第3レンズ成分G3は、アイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL31で構成されている。また、第4レンズ成分G4は、観察物体側のレンズ面及びアイポイント側のレンズ面が非球面形状に形成され、観察物体側に凹面を向けた正メニスカスレンズ形状の非球面正レンズL41で構成されている。 In the eyepiece optical system EL11, the first lens component G1 is composed of a double-convex positive aspherical lens L11 having an aspherical lens surface on the observation object side. The second lens component G2 includes a biconcave negative aspherical lens L21 having an aspherical lens surface on the observation object side and an aspherical negative lens L21 having an aspherical lens surface on the eyepoint side. It is composed of a cemented lens that is cemented with an aspherical positive lens L22 in the form of a convex positive lens. The third lens component G3 is composed of an aspherical positive lens L31 in the form of a positive meniscus lens having an aspherical lens surface on the eyepoint side and a concave surface facing the observation object side. The fourth lens component G4 is composed of an aspherical positive lens L41 in the form of a positive meniscus lens whose concave surface faces the observation object and whose observation object side lens surface and eyepoint side lens surface are aspherical. It is
この接眼光学系EL11における視度調整は、接眼光学系EL11全体を光軸方向に移動させることにより行う。 Diopter adjustment in the eyepiece optical system EL11 is performed by moving the entire eyepiece optical system EL11 in the optical axis direction.
以下の表41、接眼光学系EL11の諸元の値を掲げる。 Table 41 below lists the values of the specifications of the eyepiece optical system EL11.
(表41)第11実施例
[全体諸元]
fe = 17.623
H = 6.30
TL = 30.240
[レンズデータ]
m r d nd νd
物面 ∞ D1
1* 28.78836 7.35 1.82098 42.50
2 -11.25246 2.70
3* -7.11620 1.50 1.63550 23.89
4 564.01019 1.48 1.53110 55.91
5* -165.33547 1.00
6 -397.01843 5.95 1.53110 55.91
7* -11.70908 0.5
8* -87.51711 2.70 1.53110 55.91
9* -33.70935 D2
像面 ∞
(Table 41) Eleventh embodiment [overall specifications]
fe = 17.623
H = 6.30
TL = 30.240
[Lens data]
m r d nd νd
Object plane ∞ D1
1* 28.78836 7.35 1.82098 42.50
2 -11.25246 2.70
3* -7.11620 1.50 1.63550 23.89
4 564.01019 1.48 1.53110 55.91
5* -165.33547 1.00
6 -397.01843 5.95 1.53110 55.91
7* -11.70908 0.5
8* -87.51711 2.70 1.53110 55.91
9* -33.70935 D2
Image plane ∞
この接眼光学系EL11において、第1面、第3面、第5面、第7面、第8面及び第9面は非球面形状に形成されている。次の表42に、非球面のデータ、すなわち円錐定数K及び各非球面定数A4~A12の値を示す。 In the eyepiece optical system EL11, the first, third, fifth, seventh, eighth, and ninth surfaces are aspherical. The following Table 42 shows the data of the aspheric surface, namely the values of the conic constant K and each of the aspheric constants A4-A12.
(表42)
[非球面データ]
第1面
K= 4.9064
A4 =-1.05219E-04 A6 =-6.21990E-07 A8 = 1.81446E-08
A10=-1.14918E-10 A12= 3.47790E-13
第3面
K=-2.7141
A4 =-1.22865E-04 A6 = 1.06684E-06 A8 =-6.77704E-09
A10= 4.48572E-11 A12= 0.00000E+00
第5面
K=-0.1268
A4 = 3.96618E-04 A6 =-3.89261E-06 A8 = 2.32375E-08
A10=-1.45358E-10 A12= 0.00000E+00
第7面
K= 0.5892
A4 = 2.52841E-04 A6 =-6.99186E-07 A8 =-4.09567E-09
A10= 2.38163E-11 A12= 0.00000E+00
第8面
K= 1.0000
A4 =-1.15871E-04 A6 = 1.20055E-06 A8 =-5.20908E-09
A10= 4.32497E-11 A12= 0.00000E+00
第9面
K= 2.7036
A4 =-2.43083E-04 A6 = 2.51325E-06 A8 =-1.39088E-08
A10= 7.50477E-11 A12= 0.00000E+00
(Table 42)
[Aspheric data]
1st surface K = 4.9064
A4 = -1.05219E-04 A6 = -6.21990E-07 A8 = 1.81446E-08
A10 = -1.14918E-10 A12 = 3.47790E-13
3rd surface K=-2.7141
A4 = -1.22865E-04 A6 = 1.06684E-06 A8 = -6.77704E-09
A10= 4.48572E-11 A12= 0.00000E+00
5th surface K=-0.1268
A4 = 3.96618E-04 A6 = -3.89261E-06 A8 = 2.32375E-08
A10 = -1.45358E-10 A12 = 0.00000E+00
7th surface K = 0.5892
A4 = 2.52841E-04 A6 = -6.99186E-07 A8 = -4.09567E-09
A10= 2.38163E-11 A12= 0.00000E+00
8th surface K= 1.0000
A4 = -1.15871E-04 A6 = 1.20055E-06 A8 = -5.20908E-09
A10= 4.32497E-11 A12= 0.00000E+00
9th surface K = 2.7036
A4 = -2.43083E-04 A6 = 2.51325E-06 A8 = -1.39088E-08
A10= 7.50477E-11 A12= 0.00000E+00
この接眼光学系EL11において、観察物体と第1レンズ成分G1との軸上空気間隔D1、及び、第4レンズ成分G4とアイポイントEPとの軸上空気間隔D2は視度調節時に変化する。また、これらの間隔の変化に伴い入射瞳位置EnPも変化する。次の表43に、視度毎の可変間隔及び入射瞳位置を示す。 In this eyepiece optical system EL11, the axial air space D1 between the observation object and the first lens component G1 and the axial air space D2 between the fourth lens component G4 and the eye point EP change during dioptric adjustment. In addition, the entrance pupil position EnP also changes as these intervals change. Table 43 below shows the variable spacing and entrance pupil positions for each diopter.
(表43)
[可変間隔データ]
視度 -1dpt +2dpt -4dpt
D1 7.06 7.98 6.04
D2 20.10 19.18 21.12
EnP -27.40929 -28.67303 -26.17269
(Table 43)
[Variable interval data]
Diopter -1dpt +2dpt -4dpt
D1 7.06 7.98 6.04
D2 20.10 19.18 21.12
EnP -27.40929 -28.67303 -26.17269
次の表44に、この接眼光学系EL11の各条件式対応値を示す。 Table 44 below shows values corresponding to each conditional expression of the eyepiece optical system EL11.
(表44)
f4 =101.468
f12= 26.176
f23=-66.090
[条件式対応値]
(1)fe/f1=1.640
(2)fe/f12=0.673
(3)νd2=23.89
(4)fe/f4=0.174
(5)(G2R2-G3R1)/(G2R2+G3R1)=-0.412
(6)(G1R2+G1R1)/(G1R2-G1R1)=-0.438
(7)fe/EnP=-0.643
(8)fe/f23=-0.267
(9)D1/f1=0.657
(10)TL/fe=1.716
(11)nd1=1.821
(12)nd2=1.636
(Table 44)
f4 = 101.468
f12 = 26.176
f23=-66.090
[Value corresponding to conditional expression]
(1) fe/f1 = 1.640
(2) fe/f12 = 0.673
(3) νd2 = 23.89
(4) fe/f4 = 0.174
(5) (G2R2-G3R1)/(G2R2+G3R1) = -0.412
(6) (G1R2+G1R1)/(G1R2-G1R1)=-0.438
(7) fe/EnP = -0.643
(8) fe/f23=-0.267
(9) D1/f1 = 0.657
(10) TL/f = 1.716
(11) nd1 = 1.821
(12) nd2 = 1.636
このように、この接眼光学系EL11は、上記条件式(1)~(4)、(6)~(11)を満足している。 Thus, the eyepiece optical system EL11 satisfies the conditional expressions (1) to (4) and (6) to (11).
この接眼光学系EL11の、基準視度(-1dpt)における球面収差図、非点収差図、歪曲収差図及びコマ収差図を図22に示す。これらの各収差図より、この接眼光学系EL11は、視度調節範囲内にて良好な収差が達成されていることがわかる。 FIG. 22 shows a spherical aberration diagram, an astigmatism diagram, a distortion diagram, and a coma aberration diagram at the reference diopter (−1 dpt) of this eyepiece optical system EL11. From these aberration diagrams, it can be seen that the eyepiece optical system EL11 achieves good aberrations within the diopter adjustment range.
なお、以下に記載の内容は、光学性能を損なわない範囲で適宜採用可能である。 Note that the contents described below can be appropriately adopted within a range that does not impair the optical performance.
本実施形態では、接眼光学系ELの数値実施例として4つのレンズ成分の構成のものを示したが、例えば5つのレンズ成分等の他のレンズ構成にも適用可能である。また、最も物体側にレンズ成分を追加した構成や、最もアイポイント側にレンズ成分を追加した構成でも構わない。 In this embodiment, a configuration of four lens components is shown as a numerical example of the eyepiece optical system EL, but it is also applicable to other lens configurations such as, for example, five lens components. A configuration in which a lens component is added closest to the object side or a configuration in which a lens component is added closest to the eyepoint side may be used.
また、単独又は複数のレンズ成分を光軸に直交方向の変位成分を持つように移動させ、または、光軸を含む面内方向に回転移動(揺動)させて、手振れによって生じる像ブレを補正する防振レンズ群としてもよい。特に、第3レンズ成分G3を防振レンズ群とするのが好ましい。 Image blur caused by camera shake is corrected by moving a single or multiple lens components so that they have a displacement component in the direction perpendicular to the optical axis, or rotationally moving (oscillating) in the in-plane direction including the optical axis. An anti-vibration lens group may be used. In particular, it is preferable to use the third lens component G3 as a vibration reduction lens group.
また、本実施形態の接眼光学系ELを構成するレンズ(レンズ成分、レンズ要素)のレンズ面は、球面または平面としてもよく、或いは非球面としてもよい。レンズ面が球面または平面の場合、レンズ加工及び組立調整が容易になり、レンズ加工及び組立調整の誤差による光学性能の劣化を防げるため好ましい。また、像面がずれた場合でも描写性能の劣化が少ないので好ましい。レンズ面が非球面の場合、研削加工による非球面、ガラスを型で非球面形状に成型したガラスモールド非球面、又はガラスの表面に設けた樹脂を非球面形状に形成した複合型非球面のいずれでもよい。また、レンズ面は回折面としてもよく、レンズを屈折率分布型レンズ(GRINレンズ)或いはプラスチックレンズとしてもよい。 Further, the lens surfaces of the lenses (lens components, lens elements) forming the eyepiece optical system EL of the present embodiment may be spherical, planar, or aspherical. If the lens surface is spherical or flat, it is preferable because it facilitates lens processing and assembly adjustment and prevents deterioration of optical performance due to errors in lens processing and assembly adjustment. Also, even if the image plane is deviated, there is little deterioration in rendering performance, which is preferable. If the lens surface is aspherical, it can be aspherical by grinding, glass molded aspherical by molding glass into an aspherical shape, or composite aspherical by forming resin on the glass surface into an aspherical shape. It's okay. Further, the lens surface may be a diffractive surface, and the lens may be a gradient index lens (GRIN lens) or a plastic lens.
また、本実施形態の接眼光学系ELを構成するレンズ(レンズ成分、レンズ要素)のレンズ面には、フレアやゴーストを軽減し、高コントラストの高い光学性能を達成するために、広い波長域で高い透過率を有する反射防止膜を施してもよい。 In addition, the lens surfaces of the lenses (lens components, lens elements) that constitute the eyepiece optical system EL of this embodiment are coated with light in a wide wavelength range in order to reduce flare and ghost and achieve high optical performance with high contrast. An antireflection coating with high transmittance may be applied.
また、本実施形態の接眼光学系ELは、第1レンズ成分G1と第2レンズ成分G2と第3レンズ成分G3と第4レンズ成分G4とが一体で、又は接眼光学系EL全体が一体で移動して視度調整を行う構成を示したが、最もアイポイント側のレンズ成分を固定し、当該レンズ成分よりも観察物体側のレンズ成分全体を一体で移動したり、第1レンズ成分G1と第2レンズ成分G2と第3レンズ成分G3と第4レンズ成分G4との少なくとも一部のレンズ成分を移動したりする構成でも構わない。特に、第1レンズ成分G1を移動させ、その他のレンズ成分は視度調整時に像面に対する位置を固定とするのが好ましい。視度調整レンズ群は単レンズから構成するのが好ましい。 Further, in the eyepiece optical system EL of the present embodiment, the first lens component G1, the second lens component G2, the third lens component G3, and the fourth lens component G4 move integrally, or the entire eyepiece optical system EL moves integrally. However, the lens component closest to the eye point is fixed and the entire lens component closer to the object to be observed than that lens component is moved integrally, or the first lens component G1 and the first lens component G1 are moved together. At least some of the two lens components G2, the third lens component G3, and the fourth lens component G4 may be moved. In particular, it is preferable to move the first lens component G1 and fix the positions of the other lens components with respect to the image plane when adjusting the dioptric power. It is preferable that the diopter adjusting lens group is composed of a single lens.
EL(EL1~EL11) 接眼光学系
G1 第1レンズ成分 G2 第2レンズ成分
G3 第3レンズ成分 G4 第4レンズ成分
1 カメラ(光学機器)
EL (EL1 to EL11) eyepiece optical system G1 first lens component G2 second lens component G3 third lens component G4 fourth lens component 1 camera (optical equipment)
Claims (6)
正の屈折力を有する単レンズである第1レンズと、
観察物体側に凹面を向けたメニスカスレンズ形状の負の屈折力を有する単レンズである第2レンズと、
正の屈折力を有する単レンズである第3レンズと、
観察物体側に凹面を向けたメニスカスレンズ形状の正の屈折力を有する単レンズである第4レンズとの実質的に4個のレンズからなり、
次式の条件を満足する接眼光学系。
1.38 < fe/f1 < 1.65
1.600 < nd1 < 1.800
但し、
fe:当該接眼光学系の全系の焦点距離
f1:前記第1レンズの焦点距離
nd1:前記第1レンズの媒質のd線に対する屈折率 From the observed object side,
a first lens that is a single lens having positive refractive power;
a second lens, which is a single lens having a meniscus lens shape with a concave surface facing the observation object side and having negative refractive power;
a third lens, which is a single lens having positive refractive power;
Consists of substantially four lenses , including a fourth lens which is a single lens having positive refractive power in the form of a meniscus lens with a concave surface facing the observation object side,
An eyepiece optical system that satisfies the following conditions.
1.38<fe/f1<1.65
1.600 < nd1 < 1.800
however,
fe: focal length of the entire eyepiece optical system f1: focal length of the first lens nd1: refractive index of the medium of the first lens for the d-line
20.0 < νd2 < 35.0
但し、
νd2:前記第2レンズの媒質のd線に対するアッベ数 3. An eyepiece optical system according to claim 1, wherein said second lens satisfies the following condition.
20.0 < νd2 < 35.0
however,
νd2: Abbe number for the d-line of the medium of the second lens
次式の条件を満足する請求項1~3の何れか一項に記載の接眼光学系。
-1.00 < fe/EnP < -0.48
但し、
fe:当該接眼光学系の全系の焦点距離
EnP:基準視度における、当該接眼光学系の入射瞳位置(符号は、観察物体面を基準に、アイポイント側を正とする) The observation object is a display surface of an organic EL display,
4. An eyepiece optical system according to any one of claims 1 to 3, which satisfies the following conditions.
-1.00<fe/EnP<-0.48
however,
fe: focal length of the entire system of the eyepiece optical system EnP: entrance pupil position of the eyepiece optical system at the reference diopter (the sign is positive on the eyepoint side with respect to the observation object plane)
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