JP2004264799A - Terrestrial telescope with digital camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make it possible to perform imaging of an imager at all times and to correct a focusing position of the imager by simple and inexpensive configuration without the loss of quantity of light during photographing. <P>SOLUTION: The imager 3 is arranged behind an objective lens group 1 and a retreatable quick return half mirror 2 is arranged between the objective lens group 1 and the imager 3 as an optical path splitting means toward a viewing optical system. Plane glass 9 for correcting the change in the image formation position in the optical axis direction accompanying the retreat of the quick return half mirror 2 cooperatively with the retreat from the optical axis of the imaging optical system of the quick return half mirror 2 is inserted into the optical axis of the imaging optical system. The quick return half mirror 2 and the plane glass 9 are respectively held at both ends of a mirror guide lever 8 which is rigid single member and their respective retreat and insertion are performed. The quick return half mirror 2 may be provided with a sloping plane for correcting the deviation in the image formation position in the direction intersecting with the optical axis. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

本実施形態においては、この結像位置Ａと結像位置Ｂのずれを平面ガラス９により補正する。すなわち、レリーズボタンが全押しされると、前述のように規制レバー１１が反時計方向に回動し、これにより規制を失ったＱＲハーフミラー２が退避し、平面ガラス９が下降して光軸上に挿入され、ストッパー１５により点線の位置で係止される。
【００３６】
図３はこの撮影時に平面ガラス９が主光軸上に挿入された状態を示している。ＱＲハーフミラー２の跳ね上げ後、平面ガラス９が光軸に対し垂直に挿入されるものとすれば、この時の中心光ｌ０と周辺光ｌ１により形成される結像位置のずれδは平面ガラス９の屈折率ｎ’（平面ガラス９とＱＲハーフミラー２のガラスが同一であれば上記と同じｎの値を用いることができる）、平面ガラス９の厚さｄ’から下記の式（２）のように近似することができる。
【００３７】
【数２】

式（２）はスネルの法則と幾何学的考察によって導かれたもので、図３のように光軸に対して９０°で交差するよう平面ガラス９を挿入した場合には、式（２）のように図３の周辺光ｌ１の入射角度θ’に関連する項は微少項として無視でき、像のずれ量δは平面ガラス９の厚みｄ’とその屈折率ｎ’により決まる。
【００３８】
したがって、式（１）と式（２）の左辺の像のずれ量δが等しくなるよう、式（２）の左辺に式（１）の右辺を代入し、平面ガラス９の厚みｄ’について解けば、本実施形態で必要な平面ガラス９の厚みｄ’を計算することができる。
【００３９】
図４は、この計算結果を示している。ここでは、ＱＲハーフミラー２の厚みｄ＝１（ｍｍ）、ＱＲハーフミラー２および平面ガラス９のガラスが同一で両者の屈折率がｎ＝ｎ’＝１．５１６３３である条件において、上記の式（１）と式（２）による計算結果を示している。
【００４０】
ここで、図４の計算結果に関する考察を示しておく。
【００４１】
図４の計算結果から判るように、補正すべき像のずれ量δは図２の周辺光ｌ１の入射角度θに依存し、一定ではない。ＱＲハーフミラー２を４５°で挿入している場合、周辺光ｌ１の入射角度θの値が大きくなる程、像のずれ量δは大きくなる（ただしθ＝４５°の光線は特別な場合で、δ＝∞で非結像）。すなわち、挿入する平面ガラス９の厚みを除々に変えなければＱＲハーフミラー２で生じていた収差（コマ収差）は完全には除去できない、とも言える。一方、補正ガラスによって光軸方向にずれる量は、式（２）から明らかなようにθの影響を受けない。
【００４２】
しかしながら、実際の製品の光学設計においては、オートフォーカスのためのコントラスト計算エリアにせよ撮影像にせよ、周辺よりも中心視野を重視する、すなわち、近軸領域の（しかも入射角度θが４５°に近い）周辺光ｌ１（図２）の条件を重視して計算を行なうので、図４においても同様にθ＝４５°最近傍の計算結果を採用する、すなわち、像のずれを解消するための平面ガラス９の厚さｄ’には１．７７ｍｍを採用する。
【００４３】
平面ガラス９挿入の効果は平面ガラス９が無い時と比較して以下のように評価できる。
【００４４】
ＱＲハーフミラー２が光軸から退避している時と挿入されている時の、光軸方向での合焦位置ずれの量（δ）は、図４より平面ガラス９が無いとき：最大０．７０ｍｍであるが、平面ガラス９があるとき：厚さ１．７７ｍｍのものを挿入した場合は画角中心部のずれは補正されるので、ずれは最大０．７０−０．６０＝０．１０ｍｍの範囲となる。
【００４５】
ＱＲハーフミラー２の離脱による結像位置のずれによる影響を本実施形態のように平面ガラス９を挿入することなく放置した場合、たとえばＱＲハーフミラー２挿入中に計算したオートフォーカス制御の条件をそのまま用いることによって撮影画質の低下となって表れる。この画質低下の度合は、撮影時の光学系の被写界深度（絞り値）などによっても異なるが、被写界深度の浅い絞り開放のような条件においては場合によっては深刻なものとなる。
【００４６】
一方、本実施形態によれば、平面ガラス９を挿入することにより、ＱＲハーフミラー２が挿入されていた状態に生じていた結像位置のずれの分だけ結像位置を補正することができる。したがって、ＱＲハーフミラー２挿入中に計算したオートフォーカス制御の条件をそのまま用いても、画質低下の度合はより小さくなる。
【００４７】
特に、本実施形態によれば、平面ガラス９を光軸に垂直に挿入するようにしているので、平面ガラス９の結像位置の補正効果は種々の方向を有する全ての撮影光線について均等に作用し（式（２）が周辺光の入射角度θ’に依存しない点を参照のこと）、図４に示したように結像に関与する周辺光の方向に依存して発生する結像位置のずれに起因する画像の劣化を撮影時に生じることがない。
【００４８】
以上のようにして、本実施形態では、ＱＲハーフミラー２が光軸上から退避することで生じる結像位置（合焦位置）の変化を平面ガラス９を挿入することにより補正することができる。
【００４９】
平面ガラス９が挿入された後、撮像素子３は、レリーズボタン半押し状態のときに決定された電子シャッター開放時間だけ被写体像を撮像する。撮像が終了すると、制御回路１４は図示しない駆動モータを駆動させ、ＱＲハーフミラー２および平面ガラス９を待機位置に復帰させる。
【００５０】
以上のようにして、本実施形態によれば、ハーフミラーによる光路分割手段（ＱＲハーフミラー２）により撮像素子と観察光学系の双方に被写体光束を入射させるデジタルカメラ付地上望遠鏡において、撮影時、ハーフミラーによる光路分割手段を主光学系から除去するとともに、ハーフミラーによる光路分割手段により生じていた結像位置のずれを補正する光学素子（平面ガラス９）を主光学系に挿入するようにしているので、撮影時の撮像素子への入射光量の損失を生じることがなく、プロセッサやメモリを用いることなく、また結像位置補正用の光学素子として平面ガラス９のようにシンプルな光学素子を利用した非常に簡単安価な構成によって合焦位置のずれを補正することができる。もちろん、本実施形態ではハーフミラーによる光路分割を行なうので観察期間中は撮像素子により、露光調節、モニタ表示、オートフォーカス調整などの所定の目的のための撮像データ取得が可能である。
【００５１】
また、本実施形態によれば、光路分割手段を構成するＱＲハーフミラー２と平面ガラス９をそれぞれ別のレバー上に保持するのではなく、リジッドな１部材のガイドレバー部材（ミラーガイドレバー８）の両端にそれぞれ保持しており、このミラーガイドレバー８によりＱＲハーフミラー２ないし平面ガラス９の位置決めが行なわれる。このため、少ない部品点数で非常に簡単安価に実施でき、ＱＲハーフミラー２ないし平面ガラス９の位置決め誤差は極めて少なくて済み、正確な結像位置補正を行なえる、という優れた効果がある。
【００５２】
なお、以上では説明を容易にするため、ＱＲハーフミラー２は４５°の角度で、平面ガラス９は９０°の角度でそれぞれ主光学系に挿入されるものと説明したが、これらの条件はあくまでも便宜上のものであり、これらの部材の主光学系に対する角度は他の設計条件に応じて適宜変更することができるのはいうまでもない。
【００５３】
また、以上では、ＱＲハーフミラー２および平面ガラス９が互いになす角度は９０°であるものとして説明したが、駆動機構の構成、装置内のスペースなどの事情に応じて両者の相対角度を９０°以外の角度に取ることができるのはいうまでもない。
【００５４】
＜第２実施形態＞
以上では、ＱＲハーフミラー２を退避させる撮影時に平面ガラス９を挿入し、光軸方向の結像位置ずれδを補正する構成を示した。
【００５５】
しかしながら、第１実施形態において平面ガラス９を挿入することで補正できるのは光軸方向の結像位置ずれδであって、結像光軸のシフトについては考慮されていない。図２に示したように、傾斜してＱＲハーフミラー２を挿入することによって、光軸に交差する（垂直な）方向に結像位置ずれΔが生じるが、第１実施形態に示した構成だけではこの結像位置ずれΔは補正することができない。
【００５６】
本実施形態では、この結像光軸のシフトを解消するために、光路分割手段としてのＱＲハーフミラーの透過面をその反射面（半透過面）に対して傾斜した傾斜平面から構成する例を示す。
【００５７】
光路分割手段としての透過面をその反射面（半透過面）に対して傾斜した傾斜平面から構成する構造は、たとえば、ＱＲハーフミラー１８の垂直断面形状を図５のようなくさび形断面とするものである。
【００５８】
以下、図５の構成につき説明するが、以下の説明において図５以外の構成は第１実施形態と同様であるものとする。また、以下の説明において、第１実施形態と同一または相当するものに関しては同一符号を用い、その詳細な説明は省略する。
【００５９】
ＱＲハーフミラー１８は、図１と同様に平面ガラス９とともにミラーホルダー８に支持されて観察時にＱＲハーフミラー１８が光路に挿入され、撮影時にはＱＲハーフミラー１８が退避して平面ガラス９が光路に挿入されるよう制御される。
【００６０】
図５の構成は、ＱＲハーフミラー１８表面の反射面（半透過面）により屈折の法則によってシフトされた光束、特に中心付近の光束をＱＲハーフミラー１８の背面の透過面の傾きによって撮像素子３の中心付近へ戻すようにしていることを特徴とするものである。これにより、観察時に撮像素子３中心付近を通過する光線の経路がＱＲハーフミラー１８を挿入していない時とほぼ同様になるように補正することができる。
【００６１】
以下、図５のＱＲハーフミラー１８の背面の透過面（傾斜平面）がその表面の反射面（半透過面）に対してなす角度αの計算手法を示す。
【００６２】
ここでは、撮像素子上３の結像面から２９．５５９ｍｍの位置に厚さ１ｍｍ、屈折率ｎ＝１．５１６３３の単純平面ＱＲハーフミラーを光軸に対して４５°の角度で挿入した場合において、ＱＲハーフミラー１８の背面の透過面（傾斜平面）がその表面の反射面（半透過面）に対してなす角度αの計算手法を示す。なお図５は模式的に表したものであって、縮尺については考慮されていない。
【００６３】
このような構成においては、スネルの法則から光軸上の光線（中心光）がこのＱＲハーフミラー入射により生じる屈折角θ１はθ１＝２７．７９６°であり、よって中心光がＱＲハーフミラーを透過する光路長ＬはＬ＝１．１３０ｍｍとなる。
【００６４】
これにより、出射光（光軸に並行な破線により図示）の光軸シフト量ΔはΔ＝０．３３４ｍｍとなり、この中心光を元通り撮像素子５の中心に結像させるために必要な入射角θ２はθ２＝０．６４７°となる。
【００６５】
したがって、図５のようなくさび形状の場合、ＱＲハーフミラー１８の背面（実線）の透過面の傾斜角αは、スネルの法則から
【００６６】
【数３】

を満足する必要があり、そこでこの式（３）をαについて解くと傾斜角αはα＝０．７１０°（分秒表示で４２’３４”）となる。
【００６７】
上記のような挾角αを有するくさび形ＱＲハーフミラー１８を用いることにより、撮像素子３上において結像光軸の上下方向のシフトをキャンセルしたのと同等の効果が得られる。結像光軸の上下方向のシフトそのものはキャンセルできないが、撮像素子３の撮像面の位置においては、光軸付近では実質的に平面ガラスによるＱＲハーフミラーで生じる結像光軸の上下方向のシフトがなくなったのと同じ状態を形成できる。
【００６８】
観察期間においては、図５の状態でオートフォーカス制御を行なうことになるが、このとき、上述の計算は光軸付近の周辺光のみに関して適用されるため、オートフォーカスエリアを撮像素子３の撮像範囲の中心付近に設定すれば、結像光軸の上下方向のシフトが無いのと同等な状態でオートフォーカス処理を行なうことができる。
【００６９】
なお、光軸に沿った結像位置のずれに関しては、撮影時にＱＲハーフミラー１８を退避させ、第１実施形態と同様に構成した平面ガラス９を挿入することにより補正する。
【００７０】
すなわち、ＱＲハーフミラー１８が光軸から退避すると結像位置は撮像素子３上から光軸方向にδだけずれるが、平面ガラス９を光軸に対し垂直に挿入することで結像位置はもとの撮像素子３上になるように補正される。補正ガラス９の厚さは平面のＱＲハーフミラーを用いた場合と同じ１．７７ｍｍでよい。
【００７１】
図５のようなくさび型形状の光路分割手段（ＱＲハーフミラー１８）は、ハーフミラー構成であれば、ガラスなどの材料を整形した上、反射／透過／フィルタ特性を与えるためのコーティングを施すことにより、比較的簡単安価に製造することができる（第１実施形態のＱＲハーフミラー２も同様）。
【００７２】
なお、第１実施形態に関して示した種々の変形例（ＱＲハーフミラーの挿入角度その他）は、第２実施形態においても適用可能であることはいうまでもない。
【００７３】
【発明の効果】
以上の説明から明らかなように、本発明によれば、対物レンズ群と、前記対物レンズ群の後方に配置され前記対物レンズ群とともに撮像光学系を構成する撮像素子と、光路分割手段として前記対物レンズ群と前記撮像素子の間に配置された退避可能な光路分割手段と、前記光路分割手段により前記撮像光学系の光路外に分割された光像を観察する観察光学系と、前記光路分割手段が前記撮像光学系の光軸から退避した時、前記光路分割手段の退避に連動して、前記光路分割手段の退避に伴なう結像位置の変化を補正する光学素子を前記撮像光学系の光軸に挿入する結像位置補正手段を設けた構成を採用しているので、撮像素子の撮像を常時行なえ、撮影時の光量の損失がなく、しかも演算手段や光学素子の駆動制御手段を必要としない簡単安価な構成により撮像素子の合焦位置を補正できる、という優れた効果がある。
【００７４】
特に、前記光学素子は、前記光路分割手段の退避に伴なう光軸方向の結像位置の変化を補正する厚みを有する平面ガラスから構成することができ、その場合、シンプルな光学素子を利用した非常に簡単安価な構成によって合焦位置のずれを補正することができる。
【００７５】
あるいはさらに、一方の端部に前記光路分割手段を、他方の端部に前記光学素子を支持したガイドレバー部材により前記光路分割手段の退避と前記光学素子の挿入を制御する構成を用いれば、少ない部品点数で非常に簡単安価に、また正確に結像位置の補正を行なえる、という優れた効果が得られる。
【００７６】
あるいはさらに、前記平面ガラスが前記撮像光学系の光軸に対して垂直に挿入される構成を採用することにより、平面ガラスの結像位置の補正効果を種々の方向を有する全ての撮影光線について均等に作用させることができ、オートフォーカス制御を最適な条件で作用させるとともに撮影画質の劣化を防止できる、という優れた効果が得られる。
【００７７】
あるいはさらに、前記光路分割手段の透過面を前記光路分割手段の反射面に対して傾斜した傾斜平面から形成することにより、前記光路分割手段の挿入時と離脱時の前記撮像素子に対する中心光軸のずれによる光軸に交差する方向の結像位置ずれを補正する構成を採用することにより、光軸方向の結像位置のみならず光軸に交差する方向の結像位置ずれ（光軸シフト）も補正することができる、という優れた効果が得られる。
【００７８】
前記光路分割手段はハーフミラーから構成することができ、その場合ガラスなどの材料を整形した上、反射／透過／フィルタ特性を与えるためのコーティングを施すことにより、比較的簡単安価に製造することができる。
【図面の簡単な説明】
【図１】本発明の第１実施形態に係るデジタルカメラ付地上望遠鏡の全体構成を示した説明図である。
【図２】図１の装置において観察時に主光学系に挿入されたＱＲハーフミラーを示した説明図である。
【図３】図１の装置において撮像時に主光学系に挿入された平面ガラスを示した説明図である。
【図４】図１の装置のクイックリターンハーフミラーにより生じる像のずれ量とそれを補正する平面ガラスの厚みの算出結果を示した表図である。
【図５】本発明の第２実施形態に係るデジタルカメラ付地上望遠鏡の要部の構成を示した説明図である。
【符号の説明】
１ 対物レンズ群
１ａ 固定レンズ群
１ｂ 可動フォーカスレンズ群
２、１８ クイックリターンハーフミラー
３ 撮像素子（ＣＣＤ又はＣＭＯＳ）
４ 反射ミラー
５ リレーレンズ群
６ 焦点板
７ 接眼レンズ
８ ミラーガイドレバー
９ 平面ガラス
１０ 引張りばね
１１ 規制レバー
１１ａ、１２ 回動軸
１３ ＣＣＤドライバー
１４ 制御回路
１５ ストッパー
１６ ＡＦ用モータ
１７ レンズ枠[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a terrestrial telescope with a digital camera using an optical path splitting means for splitting an optical path into an image pickup device and an observation optical system.
[0002]
[Prior art]
BACKGROUND ART In order to observe natural animals such as wild birds, ground telescopes having a magnification of about 20 to 60 times are widely used. Generally, as a configuration of a terrestrial telescope, a configuration based on a Galilean telescope including a positive (convex) lens and a negative (concave) lens functioning as an erecting system, or a Keplerian telescope including only a positive (convex) lens is used. Although an erecting system in which a prism or the like is added to the basic configuration is known, in any case, the terrestrial telescope is configured to allow a user to observe an erect image.
[0003]
When a ground telescope is used for observing natural animals and plants, there is a demand not only to observe an object but also to record it. The applicant has disclosed in Japanese Patent Application Laid-Open Publication No. H11-163873 a configuration of a terrestrial telescope with a digital camera capable of observing a clear and bright image in order to observe an aerial image while being a system capable of already taking an observation image. In the proposal.
[0004]
The structure of the terrestrial telescope with a digital camera in Patent Document 1 is similar to the structure of a general single-lens reflex digital camera, except for the structure of the observation optical system. Uses a return mirror.
[0005]
On the other hand, a single-lens reflex digital camera differs from a silver-salt single-lens reflex camera in that a fixed half mirror that divides a light beam transmitted through a photographing lens into an optical path of an observation optical system and an image sensor is used as an optical path dividing unit. Are known. Such a structure has an advantage that the imaging device can constantly perform imaging for monitor display, autofocus processing, exposure calculation, and the like, and has a very simple and inexpensive configuration because no movable mirror is used. There is a problem that loss cannot be avoided.
[0006]
In view of this point, as shown in Patent Document 2 below, a half mirror that guides a part of the subject light flux transmitted through the objective lens to the observation optical system and guides the rest to the imaging device is configured by a quick return mirror. A structure has been proposed in which a mirror is always positioned at an observation position where a part of a subject light beam is guided to an observation optical system, and is controlled to retreat from an imaging optical path during imaging. In this Patent Document 2, when the half mirror is at the observation position, the focusing position at which the objective lens focuses on the subject when the half mirror is retracted by the photoelectric conversion output of the subject light beam incident on the imaging device via the half mirror is set. When the half mirror is actually retracted to the shooting position, the objective lens is moved to the calculated focusing position to focus on the image when the half mirror is actually retracted to the shooting position.
[0007]
[Patent Document 1]
Japanese Patent Application No. 2002-47304 (FIG. 1)
[Patent Document 2]
JP-A-2000-162495 (FIG. 1)
[0008]
[Problems to be solved by the invention]
The configuration disclosed in Patent Literature 2 has an advantage that a loss of light amount at the time of photographing a subject can be prevented, and furthermore, a shift in focus of an image incident on an image sensor when the half mirror is retracted can be corrected by moving a photographing lens. A processor and a memory for calculation and storage of focusing are required, and there is a problem that manufacturing cost is increased.
[0009]
It is an object of the present invention to solve the above-described problems, to enable constant imaging of an image sensor, to eliminate the loss of light amount at the time of shooting, and to correct the in-focus position of the image sensor with a simple and inexpensive configuration. is there.
[0010]
[Means for Solving the Problems]
According to an embodiment of the present invention, there is provided an objective lens group, an imaging element disposed behind the objective lens group and constituting an imaging optical system together with the objective lens group, and the objective lens serving as an optical path dividing unit. A retractable optical path dividing unit disposed between a group and the image pickup element, an observation optical system for observing a light image divided outside the optical path of the imaging optical system by the optical path dividing unit, and the optical path dividing unit When retracted from the optical axis of the imaging optical system, the optical element that corrects a change in an image forming position accompanying the retreat of the optical path dividing unit in conjunction with the retraction of the optical path dividing unit is changed to a light of the imaging optical system. A configuration in which an imaging position correcting unit inserted into the shaft is provided is employed.
[0011]
Alternatively, a configuration is adopted in which the optical element is a flat glass having a thickness that corrects a change in the imaging position in the optical axis direction accompanying the retreat of the optical path dividing unit.
[0012]
Alternatively, the image forming position correcting means controls the retreat of the optical path dividing means and the insertion of the optical element by a guide lever member supporting the optical path dividing means at one end and the optical element at the other end. Configuration was adopted.
[0013]
Alternatively, a configuration is adopted in which the flat glass is inserted perpendicular to the optical axis of the imaging optical system.
[0014]
Alternatively, furthermore, by forming the transmission surface of the optical path dividing means from an inclined plane inclined with respect to the reflecting surface of the optical path dividing means, the center optical axis of the image sensor at the time of insertion and departure of the optical path dividing means can be adjusted. A configuration for correcting an imaging position shift in a direction intersecting the optical axis due to the shift is adopted.
[0015]
Alternatively, the optical path dividing means is a half mirror.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
<First embodiment>
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
[0017]
FIG. 1 shows a configuration of a main part of a terrestrial telescope with a digital camera employing the present invention. In FIG. 1, the light beam transmitted through the objective lens group 1 including the fixed lens group 1a and the movable focus lens group 1b always intersects the main optical axis (the optical axis of the objective lens group 1) at an angle of 45 °. The light enters a quick return mirror (hereinafter, abbreviated as a QR half mirror) 2 that is arranged.
[0018]
The movable focus lens group 1b is held by a lens frame 17 and can be moved in the main optical axis direction by an AF motor 16.
[0019]
The light beam transmitted through the QR half mirror 2 is incident on an image pickup device (CCD, CMOS image pickup device, etc.) 3 placed on the focal plane. On the other hand, the light beam reflected by the QR half mirror 2 enters the observation optical system and is conjugated with the focal plane via a penta roof prism (not shown) or an erecting optical system combining the reflection mirror 4 and the relay lens 5. An aerial image is formed at the position of the reticle 6 placed at the position. The user can observe this image via the eyepiece 7 as an erect image.
[0020]
The reflectivity of the QR half mirror 2 is arbitrary, but if it is set to, for example, about 80% to 90% and the amount of light directed to the observation optical system is increased, the user can easily observe.
[0021]
The QR half mirror 2 is fixed to a mirror holder 8a provided at one end of a mirror guide lever 8 made of metal, plastic, or the like. The mirror guide lever 8 is pivotally supported so as to be rotatable with respect to the rotation shaft 12, and a flat glass holder 8b is provided at an end of the mirror guide lever 8 opposite to the rotation shaft 12, and this flat glass is provided. The flat glass 9 is fixed to the holder 8b. The transmittance of the flat glass 9 is almost 100%.
[0022]
In the example of FIG. 1, the QR half mirror 2 and the flat glass 9 are held by the holders 8a and 8b so as to form an angle of 90 °.
[0023]
Further, a tension spring 10 is stretched on the mirror holder 8a, and the tension spring 10 moves the mirror holder 8a and the QR half mirror 2 around the rotation shaft 12 clockwise in the figure (in a direction to retract from the photographing optical path). ).
[0024]
At the time of observation, the regulating lever 11 positions the QR half mirror 2 at a 45 ° angle with respect to the main optical axis against the tension of the tension spring 10. A notch 11b is provided at the tip of the horizontally illustrated side arm of the regulating lever 11, and the notch 11b is engaged with a pin 8c implanted in the mirror guide lever 8. The restricting lever 11 is L-shaped and is rotatably supported at its bent portion on a rotating shaft 11a. At the time of observation, a solenoid or other solenoid interlocked with a release button (not shown) for a user to perform a shooting operation is provided. The position of the solid line is maintained by the mechanical means of (1). Thus, at the time of observation, the QR half mirror 2 holds the position at 45 ° with respect to the main optical axis.
[0025]
When the photographing operation is started in response to the photographing operation of the user, the holding of the regulating lever 11 is released, and the mirror guide lever 8 is rapidly rotated clockwise by the rotational urging force of the tension spring 10, and the mirror holder is rotated. 8a and the QR half mirror 2 move to positions indicated by dotted lines, respectively.
[0026]
As described above, since the QR half mirror 2 and the flat glass 9 are held by the mirror holders 8a and 8b in a positional relationship of exactly 90 °, when the QR half mirror 2 moves to a horizontal position as indicated by a dotted line, The glass 9 moves to a position where the glass 9 is inserted immediately before the image pickup device 3 with a posture of 90 ° with respect to the optical axis of the objective lens group 1. The position of the flat glass 9 (QR half mirror 2) at the time of this photographing is determined by locking the flat glass holder 8b to the stopper 15.
[0027]
As a result, the entire amount of light transmitted through the objective lens group 1 reaches the image sensor 3, and a light image of a subject enters the image sensor 3 without loss of light by the QR half mirror 2.
[0028]
The imaging device 3 is driven by a CCD driver 13, and an imaging output of the imaging device 3 is input to a control circuit 14 including a microprocessor and a memory via the CCD driver 13. The control circuit 14 records the image data obtained from the image sensor 3 at the time of photographing on a recording medium (not shown) such as a memory card. Further, in the present embodiment, since the luminous flux of the subject is incident on the image pickup device 3 via the QR half mirror 2 even during the observation period, an unillustrated image data is obtained based on the image pickup information from the image pickup device 3 obtained in accordance with this. Processing such as monitor display on a display, autofocus processing (control of the movable focus lens group 1b via the AF motor 16), and exposure calculation (exposure amount control by half-pressing a release button, etc.) can be executed.
[0029]
Next, the operation of the terrestrial telescope with a digital camera configured as described above will be described.
[0030]
When the user half-presses a release button (not shown) and turns on a half-press switch (not shown) in a state where the QR half mirror 2 is in the solid line position in FIG. The brightness is detected by the photoelectric conversion output of the subject light beam incident on the image pickup device 3 via the mirror 2, and the contrast is detected by a known contrast detection method.
[0031]
Thereby, the control circuit 14 determines the electronic shutter opening time of the image sensor 3 according to the detected brightness of the subject light flux, and drives the AF motor 16 according to the detected contrast information, and the lens frame 17. The automatic focus control can be performed by moving the movable focus lens group 1b held in the optical axis direction. That is, the control circuit 14 drives the AF motor 16 so that the contrast of the image captured by the image sensor 3 is maximized in accordance with the change in the contrast of the subject imaged on the image sensor 3 and the movable focus lens group 1b Is moved to the in-focus position.
[0032]
Since the focus position at this time is based on the photoelectric output of the subject light image transmitted through the QR half mirror 2 and incident on the image sensor 3, when the QR half mirror 2 is flipped up and retracted, the flat glass 9 If is not inserted, the in-focus position at that time is different.
[0033]
That is, as shown in FIG. 2, if the position of an image formed through the QR half mirror 2 having the thickness d is A, and the position of the image when there is neither the QR half mirror 2 nor the flat glass 9 is B, then QR Since the refractive index n of the half mirror 2 is n> 1 (the refractive index of air n = 1), the image forming position A is always located farther from the image forming position B and farther from the QR half mirror 2.
[0034]
The shift amount δ (BA) of the imaging position when the QR half mirror 2 shown in FIG. 2 is provided and when the QR half mirror 2 and the flat glass 9 are not provided is determined by the center light 10 and the peripheral light 11 on the optical axis. Focusing on the movement of the image position, this geometric relationship can be expressed by the following equation (1). At this time, the refractive index of the glass (or other suitable material) of the QR half mirror 2 is n, the incident angle of the center light 10 on the QR half mirror 2 is 45 °, and the incident light of the peripheral light 11 on the QR half mirror 2. The angle is assumed to be θ.
[0035]
(Equation 1)

In the present embodiment, the deviation between the image forming position A and the image forming position B is corrected by the flat glass 9. That is, when the release button is fully pressed, the regulating lever 11 rotates counterclockwise as described above, whereby the QR half mirror 2 which has lost the regulation is retracted, and the flat glass 9 descends to move the optical axis. And is locked at the position indicated by the dotted line by the stopper 15.
[0036]
FIG. 3 shows a state in which the flat glass 9 is inserted on the main optical axis during this photographing. Assuming that the flat glass 9 is inserted perpendicularly to the optical axis after the QR half mirror 2 is flipped up, the deviation δ of the imaging position formed by the center light 10 and the peripheral light 11 at this time is equal to the flat glass. From the refractive index n ′ of 9 (if the glass of the flat glass 9 and the glass of the QR half mirror 2 are the same, the same value of n can be used) and the thickness d ′ of the flat glass 9, the following equation (2) is used. Can be approximated as follows.
[0037]
(Equation 2)

Equation (2) is derived from Snell's law and geometric considerations. When the plane glass 9 is inserted so as to intersect the optical axis at 90 ° as shown in FIG. The term relating to the incident angle θ ′ of the peripheral light 11 in FIG. 3 can be ignored as a minute term, and the image shift amount δ is determined by the thickness d ′ of the flat glass 9 and its refractive index n ′.
[0038]
Therefore, substituting the right side of equation (1) for the left side of equation (2) and solving for the thickness d 'of the flat glass 9 so that the shift amount δ of the image on the left side of equation (1) and equation (2) becomes equal. For example, the thickness d ′ of the flat glass 9 required in the present embodiment can be calculated.
[0039]
FIG. 4 shows the result of this calculation. Here, under the condition that the thickness d of the QR half mirror 2 is 1 mm, the glass of the QR half mirror 2 and the glass of the flat glass 9 are the same, and the refractive indices of both are n = n ′ = 1.51633, the above equation is used. The calculation results by (1) and Expression (2) are shown.
[0040]
Here, consideration regarding the calculation results of FIG. 4 will be described.
[0041]
As can be seen from the calculation results in FIG. 4, the shift amount δ of the image to be corrected depends on the incident angle θ of the peripheral light 11 in FIG. 2 and is not constant. When the QR half mirror 2 is inserted at 45 °, the larger the value of the incident angle θ of the peripheral light 11 becomes, the larger the image shift amount δ becomes. (However, a ray at θ = 45 ° is a special case. non-image at δ = ∞). That is, it can be said that the aberration (coma aberration) generated in the QR half mirror 2 cannot be completely removed unless the thickness of the flat glass 9 to be inserted is gradually changed. On the other hand, the amount of shift in the optical axis direction due to the correction glass is not affected by θ as is clear from equation (2).
[0042]
However, in the optical design of an actual product, the center field of view is more important than the periphery, whether in the contrast calculation area for autofocus or in the photographed image, that is, in the paraxial region (and the incident angle θ is 45 °). Since the calculation is performed with emphasis on the condition of the (near) ambient light 11 (FIG. 2), the calculation result closest to θ = 45 ° is similarly used in FIG. 4, that is, a plane for eliminating the image shift. 1.77 mm is adopted as the thickness d ′ of the glass 9.
[0043]
The effect of inserting the flat glass 9 can be evaluated as follows as compared with the case where the flat glass 9 is not provided.
[0044]
The amount (δ) of the focusing position shift in the optical axis direction when the QR half mirror 2 is retracted from the optical axis and when the QR half mirror 2 is inserted is from FIG. Although it is 70 mm, when there is a flat glass 9: When a glass having a thickness of 1.77 mm is inserted, the deviation at the center of the angle of view is corrected. Range.
[0045]
When the influence of the deviation of the imaging position due to the detachment of the QR half mirror 2 is left without inserting the flat glass 9 as in the present embodiment, for example, the auto focus control conditions calculated during the insertion of the QR half mirror 2 are left as they are. The use of the image causes a reduction in image quality. The degree of the image quality deterioration varies depending on the depth of field (aperture value) of the optical system at the time of photographing, but becomes serious in some cases under conditions such as opening the aperture with a shallow depth of field.
[0046]
On the other hand, according to the present embodiment, by inserting the flat glass 9, it is possible to correct the imaging position by an amount corresponding to the deviation of the imaging position that occurred when the QR half mirror 2 was inserted. Therefore, even if the conditions of the auto focus control calculated during the insertion of the QR half mirror 2 are used as they are, the degree of image quality deterioration becomes smaller.
[0047]
In particular, according to the present embodiment, since the flat glass 9 is inserted perpendicular to the optical axis, the effect of correcting the image forming position of the flat glass 9 works equally for all imaging light rays having various directions. (See the point that equation (2) does not depend on the incident angle θ ′ of the ambient light), and as shown in FIG. 4, the position of the imaging position generated depending on the direction of the ambient light involved in the image formation is determined. The deterioration of the image due to the displacement does not occur at the time of shooting.
[0048]
As described above, in the present embodiment, a change in the imaging position (focusing position) caused by the retreat of the QR half mirror 2 from the optical axis can be corrected by inserting the flat glass 9.
[0049]
After the flat glass 9 is inserted, the image sensor 3 captures a subject image for the electronic shutter opening time determined when the release button is half-pressed. When the imaging is completed, the control circuit 14 drives a drive motor (not shown) to return the QR half mirror 2 and the flat glass 9 to the standby position.
[0050]
As described above, according to the present embodiment, in the terrestrial telescope with a digital camera in which the subject light flux enters both the image sensor and the observation optical system by the optical path splitting means (QR half mirror 2) using a half mirror, The optical path splitting means by the half mirror is removed from the main optical system, and an optical element (flat glass 9) for correcting the shift of the image forming position caused by the optical path splitting means by the half mirror is inserted into the main optical system. Therefore, there is no loss of the amount of light incident on the image sensor at the time of photographing, no processor or memory is used, and a simple optical element such as a flat glass 9 is used as an optical element for correcting an image forming position. The deviation of the focus position can be corrected by a very simple and inexpensive configuration. Of course, in the present embodiment, since the optical path is divided by the half mirror, during the observation period, it is possible to obtain image data for a predetermined purpose such as exposure adjustment, monitor display, and auto focus adjustment by the image sensor.
[0051]
Further, according to the present embodiment, the QR half mirror 2 and the flat glass 9 constituting the optical path splitting means are not held on separate levers, but are one rigid guide lever member (mirror guide lever 8). The mirror guide lever 8 positions the QR half mirror 2 or the flat glass 9. Therefore, the present invention has an excellent effect that it can be implemented very simply and inexpensively with a small number of parts, the positioning error of the QR half mirror 2 or the flat glass 9 is extremely small, and accurate image position correction can be performed.
[0052]
Note that, in the above description, the QR half mirror 2 is inserted into the main optical system at an angle of 45 ° and the flat glass 9 is inserted into the main optical system at an angle of 90 ° for ease of explanation. It is for convenience, and it goes without saying that the angles of these members with respect to the main optical system can be appropriately changed according to other design conditions.
[0053]
In the above description, the angle formed between the QR half mirror 2 and the flat glass 9 is 90 °. However, the relative angle between the two is set to 90 ° depending on the configuration of the drive mechanism and the space in the apparatus. It goes without saying that the angle can be set to other angles.
[0054]
<Second embodiment>
In the above, the configuration has been described in which the flat glass 9 is inserted at the time of photographing in which the QR half mirror 2 is retracted, and the imaging position shift δ in the optical axis direction is corrected.
[0055]
However, in the first embodiment, what can be corrected by inserting the flat glass 9 is the imaging position shift δ in the optical axis direction, and the shift of the imaging optical axis is not considered. As shown in FIG. 2, when the QR half mirror 2 is inserted in an inclined manner, an imaging position shift Δ occurs in a direction intersecting (perpendicular to) the optical axis, but only the configuration shown in the first embodiment is used. In this case, the imaging position deviation Δ cannot be corrected.
[0056]
In the present embodiment, in order to eliminate the shift of the imaging optical axis, an example is described in which the transmission surface of the QR half mirror as an optical path splitting unit is constituted by an inclined plane inclined with respect to the reflection surface (semi-transmission surface). Show.
[0057]
In a structure in which the transmission surface as the optical path dividing means is formed by an inclined plane inclined with respect to the reflection surface (semi-transmission surface), for example, the vertical cross-sectional shape of the QR half mirror 18 is a wedge-shaped cross-section as shown in FIG. Things.
[0058]
Hereinafter, the configuration of FIG. 5 will be described. In the following description, the configuration other than FIG. 5 is the same as that of the first embodiment. In the following description, the same or corresponding components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof will be omitted.
[0059]
The QR half mirror 18 is supported by the mirror holder 8 together with the flat glass 9 as in FIG. 1 and the QR half mirror 18 is inserted into the optical path at the time of observation, and the QR half mirror 18 is retracted and the flat glass 9 is moved into the optical path at the time of photographing. It is controlled to be inserted.
[0060]
In the configuration of FIG. 5, the light beam shifted by the refraction law by the reflection surface (semi-transmission surface) on the surface of the QR half mirror 18, particularly the light beam near the center, is formed by the inclination of the transmission surface on the back surface of the QR half mirror 18. Is returned to the vicinity of the center. Thereby, it is possible to correct so that the path of the light beam passing near the center of the image sensor 3 during observation is almost the same as when the QR half mirror 18 is not inserted.
[0061]
Hereinafter, a calculation method of the angle α formed by the transmission surface (inclined plane) on the back surface of the QR half mirror 18 of FIG. 5 with respect to the reflection surface (semi-transmission surface) thereof will be described.
[0062]
Here, a case where a simple flat QR half mirror having a thickness of 1 mm and a refractive index of n = 1.51633 is inserted at an angle of 45 ° with respect to the optical axis at a position 29.559 mm from the imaging surface of the image sensor 3 is described. , A calculation method of an angle α formed by the transmission surface (inclined plane) on the back surface of the QR half mirror 18 with respect to the reflection surface (semi-transmission surface) of the surface. Note that FIG. 5 is a schematic representation and does not take into account the scale.
[0063]
In such a configuration, the refraction angle θ1 at which the light beam (center light) on the optical axis (center light) is incident upon the QR half mirror is θ1 = 27.796 ° from Snell's law, so that the center light passes through the QR half mirror. The optical path length L is L = 1.130 mm.
[0064]
As a result, the optical axis shift amount Δ of the emitted light (shown by a broken line parallel to the optical axis) becomes 0.334 mm, and the incident angle required to focus this center light on the center of the image sensor 5 as before. θ2 is θ2 = 0.647 °.
[0065]
Therefore, in the case of the wedge shape as shown in FIG. 5, the inclination angle α of the transmission surface on the back surface (solid line) of the QR half mirror 18 is given by Snell's law.
[Equation 3]

Therefore, when this equation (3) is solved for α, the inclination angle α is α = 0.710 ° (42′34 ″ in minutes and seconds).
[0067]
By using the wedge-shaped QR half mirror 18 having the above-described included angle α, the same effect as canceling the vertical shift of the imaging optical axis on the image sensor 3 can be obtained. Although the vertical shift of the imaging optical axis itself cannot be canceled, at the position of the imaging surface of the image sensor 3, the vertical shift of the imaging optical axis caused by the QR half mirror substantially made of flat glass near the optical axis. The same state as the disappearance can be formed.
[0068]
During the observation period, the autofocus control is performed in the state shown in FIG. 5. At this time, the above calculation is applied only to the peripheral light near the optical axis. , The autofocus process can be performed in a state equivalent to that there is no vertical shift of the imaging optical axis.
[0069]
The deviation of the imaging position along the optical axis is corrected by retracting the QR half mirror 18 during photographing and inserting the flat glass 9 configured in the same manner as in the first embodiment.
[0070]
That is, when the QR half mirror 18 retreats from the optical axis, the image forming position shifts by δ from the image pickup device 3 in the optical axis direction, but the image forming position is originally reduced by inserting the flat glass 9 perpendicularly to the optical axis. Is corrected so as to be on the image sensor 3. The thickness of the correction glass 9 may be 1.77 mm, which is the same as when a flat QR half mirror is used.
[0071]
The wedge-shaped optical path splitting means (QR half mirror 18) as shown in FIG. 5 is a half mirror configuration in which a material such as glass is shaped and a coating for giving reflection / transmission / filter characteristics is applied. Accordingly, it can be manufactured relatively easily and inexpensively (the same applies to the QR half mirror 2 of the first embodiment).
[0072]
It is needless to say that various modifications (the insertion angle of the QR half mirror and the like) shown in the first embodiment are also applicable to the second embodiment.
[0073]
【The invention's effect】
As is apparent from the above description, according to the present invention, an objective lens group, an imaging element arranged behind the objective lens group and constituting an imaging optical system together with the objective lens group, and the objective lens as optical path dividing means A retractable optical path dividing unit disposed between a lens group and the image sensor, an observation optical system for observing a light image divided outside the optical path of the imaging optical system by the optical path dividing unit, and the optical path dividing unit When retracted from the optical axis of the imaging optical system, an optical element that corrects a change in an imaging position associated with the retraction of the optical path dividing unit in conjunction with the retraction of the optical path dividing unit is provided in the imaging optical system. Uses a configuration with an imaging position correction means inserted into the optical axis, so that the image sensor can always be imaged, there is no loss of light quantity at the time of shooting, and there is a need for arithmetic means and drive control means for the optical element. And not easy cheap Can be corrected in-focus position of the imaging device by Do arrangement, there is excellent effect that.
[0074]
In particular, the optical element can be made of a flat glass having a thickness that corrects a change in the imaging position in the optical axis direction accompanying the retreat of the optical path splitting unit. In this case, a simple optical element is used. The deviation of the focus position can be corrected by a very simple and inexpensive configuration.
[0075]
Alternatively, if the configuration in which the retreat of the optical path dividing means and the insertion of the optical element are controlled by a guide lever member that supports the optical path dividing means at one end and the optical element at the other end is used, An excellent effect is obtained that the imaging position can be corrected very simply and inexpensively and accurately with the number of parts.
[0076]
Alternatively, by adopting a configuration in which the flat glass is inserted perpendicularly to the optical axis of the imaging optical system, the effect of correcting the imaging position of the flat glass can be made uniform for all photographing light rays having various directions. This makes it possible to obtain an excellent effect that the auto focus control can be operated under the optimum condition and the photographing image quality can be prevented from deteriorating.
[0077]
Alternatively, furthermore, by forming the transmission surface of the optical path dividing means from an inclined plane inclined with respect to the reflecting surface of the optical path dividing means, the center optical axis of the image sensor at the time of insertion and departure of the optical path dividing means can be adjusted. By adopting a configuration that corrects an imaging position shift in a direction intersecting the optical axis due to a shift, not only an imaging position in the optical axis direction but also an imaging position shift (optical axis shift) in a direction intersecting the optical axis. An excellent effect of being able to correct is obtained.
[0078]
The optical path splitting means can be constituted by a half mirror. In this case, a material such as glass is shaped, and a coating for giving reflection / transmission / filter characteristics is applied, thereby making it relatively easy and inexpensive to manufacture. it can.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an entire configuration of a terrestrial telescope with a digital camera according to a first embodiment of the present invention.
FIG. 2 is an explanatory view showing a QR half mirror inserted into a main optical system at the time of observation in the apparatus of FIG. 1;
FIG. 3 is an explanatory diagram showing a flat glass inserted into a main optical system at the time of imaging in the apparatus of FIG. 1;
FIG. 4 is a table showing the amount of image shift generated by a quick return half mirror of the apparatus of FIG. 1 and the calculation result of the thickness of flat glass for correcting the amount of image shift;
FIG. 5 is an explanatory diagram showing a configuration of a main part of a terrestrial telescope with a digital camera according to a second embodiment of the present invention.
[Explanation of symbols]
Reference Signs List 1 Objective lens group 1a Fixed lens group 1b Movable focus lens group 2, 18 Quick return half mirror 3 Image sensor (CCD or CMOS)
4 Reflection mirror 5 Relay lens group 6 Focusing plate 7 Eyepiece 8 Mirror guide lever 9 Flat glass 10 Tension spring 11 Restriction levers 11a, 12 Rotating shaft 13 CCD driver 14 Control circuit 15 Stopper 16 AF motor 17 Lens frame

Claims (6)

An objective lens group,
An image sensor that is arranged behind the objective lens group and constitutes an imaging optical system together with the objective lens group;
Retractable optical path dividing means disposed between the objective lens group and the image sensor as an optical path dividing means,
An observation optical system that observes the optical image divided outside the optical path of the imaging optical system by the optical path dividing unit;
When the optical path splitting unit is retracted from the optical axis of the imaging optical system, the optical element for correcting a change in an image forming position accompanying the retreat of the optical path dividing unit is interlocked with the retreat of the optical path dividing unit. A terrestrial telescope with a digital camera, comprising an image position correcting means inserted into the optical axis of the imaging optical system. 2. The terrestrial telescope with a digital camera according to claim 1, wherein the optical element is a flat glass having a thickness for correcting a change in an imaging position in an optical axis direction accompanying the retreat of the optical path dividing unit. The image forming position correcting means controls the retreat of the optical path dividing means and the insertion of the optical element by a guide lever member supporting the optical path dividing means at one end and the optical element at the other end. The terrestrial telescope with a digital camera according to claim 1. The terrestrial telescope with a digital camera according to claim 2, wherein the flat glass is inserted perpendicular to an optical axis of the imaging optical system. By forming the transmission surface of the optical path splitting unit from an inclined plane inclined with respect to the reflection surface of the optical path splitting unit, light due to a shift of a center optical axis with respect to the image pickup device when the optical path splitting unit is inserted and when the optical path splitting unit is separated from the imaging device. 2. The terrestrial telescope with a digital camera according to claim 1, wherein an image position shift in a direction intersecting the axis is corrected. The terrestrial telescope with a digital camera according to claim 5, wherein the optical path dividing means is a half mirror.

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