JPH0764045A - Projection optical system - Google Patents

Projection optical system

Info

Publication number
JPH0764045A
JPH0764045A JP5230763A JP23076393A JPH0764045A JP H0764045 A JPH0764045 A JP H0764045A JP 5230763 A JP5230763 A JP 5230763A JP 23076393 A JP23076393 A JP 23076393A JP H0764045 A JPH0764045 A JP H0764045A
Authority
JP
Japan
Prior art keywords
image
mirror
light
incident
screen
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
JP5230763A
Other languages
Japanese (ja)
Other versions
JP3475456B2 (en
Inventor
Toru Yoshida
徹 吉田
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Casio Computer Co Ltd
Original Assignee
Casio Computer Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Casio Computer Co Ltd filed Critical Casio Computer Co Ltd
Priority to JP23076393A priority Critical patent/JP3475456B2/en
Publication of JPH0764045A publication Critical patent/JPH0764045A/en
Application granted granted Critical
Publication of JP3475456B2 publication Critical patent/JP3475456B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Landscapes

  • Optical Elements Other Than Lenses (AREA)
  • Liquid Crystal (AREA)
  • Projection Apparatus (AREA)

Abstract

PURPOSE:To provide a projection optical system making all the light of a picture from a picture projection means incident on the surface of a screen at a fixed angle without causing the difference of incident angles. CONSTITUTION:The projection optical system enlarging and projecting the picture from the picture projection means on the screen is provided with a mirror 10 formed to be a curved surface reflecting all the light of the picture of the picture projection means toward the screen in an identical direction. Therefore, since all the light of the picture from the picture projection means is reflected in the identical direction by the mirror 10, all the light reflected on the mirror 10 can be made incident on the screen at the fixed angle without causing the difference of the incident angles.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】この発明は、テレビジョン映像な
どの画像をスクリーンに拡大投影する投影型画像表示装
置の投影光学系に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a projection optical system of a projection type image display device for enlarging and projecting an image such as a television image on a screen.

【0002】[0002]

【従来の技術】一般に、投影型画像表示装置は、液晶表
示パネルなどの画像形成手段で形成されたテレビジョン
映像などの画像を投影光学系によってスクリーンに拡大
投影し、これにより画面サイズの小さい画像形成手段を
用いて、大画面の画像を得ることができるようになって
いる。このような投影型画像表示装置には、本体装置と
別に配置されたスクリーンに画像を投影する方式のもの
と、本体装置の前面に設けられた透過型スクリーンの背
面に画像を投影して透過型スクリーンの前面側から投影
された画像を観察する方式のもとがある。ここでは後者
の方式について説明する。2. Description of the Related Art In general, a projection type image display device enlarges and projects an image such as a television image formed by an image forming means such as a liquid crystal display panel onto a screen by a projection optical system, thereby an image having a small screen size. A large-screen image can be obtained by using the forming means. Such a projection-type image display device is of a type that projects an image on a screen that is arranged separately from the main body device, and a projection-type image display device that projects an image on the back surface of a transmissive screen provided on the front surface of the main body device. There is a method of observing an image projected from the front side of the screen. Here, the latter method will be described.

【0003】図5はその後者の方式の一例を示した概略
構成図である。この投影型画像表示装置は、本体装置1
の前面(同図では上面)に透過型スクリーン2が設けら
れ、本体装置1の内部に画像投影手段としてのプロジェ
クタユニット3、およびこのプロジェクタユニット3か
らの画像をスクリーン2に投影する投影光学系4が設け
られた構造となっている。この場合、透過型スクリーン
2は、入射した光を均一に拡散させる拡散板、あるいは
拡散板の入射面にレンチキュラレンズを一体に形成した
ものなどである。プロジェクタユニット3は、液晶表示
パネルなどの画像形成手段、この画像形成手段によって
形成された画像を投影する投影レンズからなっている。
この場合、画像形成手段が液晶表示パネルであるとき
は、その背面に光を照射する光源を備えている。投影光
学系4は、プロジェクタユニット3からの画像の光をス
クリーン2に向けて反射するミラー5と、このミラー5
で反射された光を平行光に集光させるフレネルレンズ6
とからなっている。この投影光学系4では、図6に示す
ように、投射点Aから投影された画像が光軸7に対して
垂直な面(面BC)に結像されるとしたとき、面BCの
傾角θ1(=∠ABC)を2等分したBD部にミラー5
を配置することにより、このミラー5で反射した光の画
像を線分AB上に位置する面EBに結像させる、いわゆ
るノーマル光学系を採用している。FIG. 5 is a schematic diagram showing an example of the latter method. This projection-type image display device includes a main unit 1
A transmissive screen 2 is provided on the front surface (upper surface in the figure) of the projector, a projector unit 3 as an image projecting means inside the main body device 1, and a projection optical system 4 for projecting an image from the projector unit 3 onto the screen 2. Has a structure. In this case, the transmissive screen 2 is, for example, a diffusion plate that uniformly diffuses incident light, or one in which a lenticular lens is integrally formed on the incident surface of the diffusion plate. The projector unit 3 includes an image forming unit such as a liquid crystal display panel and a projection lens that projects an image formed by the image forming unit.
In this case, when the image forming means is a liquid crystal display panel, a light source for irradiating light is provided on the back surface thereof. The projection optical system 4 includes a mirror 5 that reflects light of an image from the projector unit 3 toward the screen 2, and the mirror 5.
Fresnel lens 6 that collects the light reflected by
It consists of In the projection optical system 4, as shown in FIG. 6, when the image projected from the projection point A is formed on a plane (plane BC) perpendicular to the optical axis 7, the tilt angle θ of the plane BC is shown. 1 (= ∠ABC) is divided into two equal parts, and the mirror 5
Is used to form an image of the light reflected by the mirror 5 on the surface EB located on the line segment AB, a so-called normal optical system is employed.

【0004】しかしながら、このような投影光学系4で
は、ミラー5を用いないものに比べて投影型画像表示装
置全体の厚さを薄くすることができるが、装置全体の厚
さdは線分ABから点Dまでの距離となるため、これ以
上の薄型化を図ることができない。すなわち、更なる薄
型化を図るためには、面BCの傾角θ1をできる限り小
さくする必要があるが、プロジェクタユニット3の投影
レンズのFナンバーを考慮すると、光軸7上における投
射点Aから面BCの点Fまでの距離L1の最小値が限定
されてしまうため、どうしても装置全体を厚さd以下に
薄くすることができない。However, in the projection optical system 4 as described above, the thickness of the entire projection type image display device can be made smaller than that without the mirror 5, but the thickness d of the entire device is the line segment AB. Since the distance is from the point D to the point D, further thinning cannot be achieved. That is, in order to further reduce the thickness, it is necessary to make the tilt angle θ 1 of the surface BC as small as possible. However, considering the F number of the projection lens of the projector unit 3, from the projection point A on the optical axis 7, Since the minimum value of the distance L 1 to the point F on the surface BC is limited, it is impossible to make the entire device thinner than the thickness d.

【0005】このような問題を解消するために、最近で
は、図7に示すように、投射点Aから投影された画像を
光軸7に対して傾いた面(面BG)に結像させ、面BG
の傾角θ2(=∠ABG)を2等分したBH部にミラー
8を偏心させて配置し、このミラー5で画像の光を反射
し、反射された光の画像を線分AB上に位置する面IB
に結像させる、いわゆるチルト(偏心)光学系を採用し
た投影光学系を導入することが検討されている。In order to solve such a problem, recently, as shown in FIG. 7, an image projected from the projection point A is formed on a surface (plane BG) inclined with respect to the optical axis 7, Surface BG
The mirror 8 is eccentrically placed at the BH part that bisects the inclination angle θ 2 (= ∠ABG) of the image, and the image light is reflected by this mirror 5, and the image of the reflected light is positioned on the line segment AB. Surface IB
It is being considered to introduce a projection optical system that employs a so-called tilt (decentering) optical system for forming an image on the.

【0006】[0006]

【発明が解決しようとする課題】このようなチルト光学
系を採用した投影光学系では、面BGの傾角θ2の自由
度が大きいため、装置全体のより一層の薄型化が可能に
なるが、ミラー8によって結像される面IBへの光の入
射角に図7の点Bの部分と点Gの部分とで20〜30°
程度の角度差が生じるため、良好な投影画像が得られな
いという問題がある。なお、このような入射角差を1枚
のフレネルレンズ6で補正しようとすると、図7の点J
を中心とするFナンバーの非常に小さなレンズの一部
(BG部)を利用することになるため、現実性に欠け
る。また、仮に複数のフレネルレンズを用いて数回にわ
たって補正しようとしても、入射角差が20〜30°程
度と大きいため、良好な配光分布が望めない。この発明
は、上記事情に鑑みてなされたもので、画像投影手段か
らの画像の光をスクリーン面に対して入射角差が生じる
ことなく全て一定の角度で入射させることのできる投影
光学系を提供することを目的とする。In the projection optical system adopting such a tilt optical system, since the degree of freedom of the tilt angle θ 2 of the surface BG is large, it is possible to make the entire device thinner. The incident angle of light on the surface IB formed by the mirror 8 is 20 to 30 ° between the point B and the point G in FIG.
There is a problem in that a good projection image cannot be obtained because of a slight angle difference. Incidentally, if it is attempted to correct such an incident angle difference with one Fresnel lens 6, a point J in FIG.
Since a part (BG portion) of a lens having a very small F number centering on is used, it is not realistic. Further, even if the correction is performed several times using a plurality of Fresnel lenses, the difference in the incident angles is as large as about 20 to 30 °, so that a good light distribution cannot be expected. The present invention has been made in view of the above circumstances, and provides a projection optical system capable of making light of an image from an image projecting unit incident at a constant angle on the screen surface without causing a difference in incident angle. The purpose is to do.

【0007】[0007]

【課題を解決するための手段】この発明は、上記目的を
達成するために、画像投影手段からの画像をスクリーン
に拡大投影する投影光学系において、画像投影手段から
の画像の光をスクリーンに向けて全て同じ向きに反射す
る曲面に形成されたミラーを備えたものである。To achieve the above object, the present invention is directed to a projection optical system for enlarging and projecting an image from an image projecting means onto a screen, and directing light of the image from the image projecting means onto the screen. All of them are provided with a mirror formed on a curved surface that reflects in the same direction.

【0008】[0008]

【作用】この発明によれば、画像投影手段からの画像の
光をミラーが全て同じ向きに反射するので、ミラーで反
射された光をスクリーンに対して入射角差が生じること
なく全て一定の角度で入射させることができる。この場
合、請求項2に記載の如く、ミラーとスクリーンとの間
にミラーで反射された光のスクリーンに対する入射角を
補正する入射角補正手段を介在させれば、入射角補正手
段によってスクリーンに入射する光の入射角を適正な入
射角に補正することができ、良好な配光分布を得ること
ができる。According to the present invention, since the mirror reflects all the light of the image from the image projecting means in the same direction, the light reflected by the mirror has a constant angle with respect to the screen without any difference in the incident angle. Can be made incident. In this case, if the incident angle correcting means for correcting the incident angle of the light reflected by the mirror with respect to the screen is interposed between the mirror and the screen, the incident angle correcting means makes the incident on the screen. The incident angle of the incident light can be corrected to an appropriate incident angle, and a good light distribution can be obtained.

【0009】[0009]

【実施例】以下、図1〜図4を参照して、この発明の一
実施例を説明する。なお、図5〜図7に示された従来例
と同一部分には同一符号を付し、その説明は省略する。
図1および図2はこの発明の投影光学系のミラーの原理
を示し、図1はx軸を基点とするy−z平面図、図2は
z軸を基点とするx−y平面図である。図1において、
z軸上の任意の点Aを投射点とし、この投射点Aを通る
プロジェクタユニット3の画像が結像面(面MN)に結
像されるチルト光学系とする。すなわち、面MNは投射
点Aと面MNの中点Kと通る光軸7に対して傾斜してお
り、線分MNの延長線とz軸とのなす角がチルト角にな
っている。そして、投射点Aと面MNの間にミラー10
を配置する。このミラー10は、投射点Aを曲率中心
(焦点)とし、y軸とz軸の交点であるx軸を通り、か
つ傾角θ3を2等分する線分MQに接近する放物面(曲
面M11)に形成され、この放物面の一部、つまり線分
AM上の点M1と線分AN上の点N1と間の曲面M11
投射点Aからの投射光(画像光)を全てz軸と平行に反
射して曲面M22に結像させるようになっている。ま
た、図2においては、z軸上の点Aが投射点となってお
り、ミラー10は、z軸上の投射点Aを中心とし、y軸
上の線分M11上の任意の点を通る同心円状(円弧M11
12〜円弧N1112)に連続する湾曲した放物面となっ
ている。DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. The same parts as those of the conventional example shown in FIGS. 5 to 7 are designated by the same reference numerals, and the description thereof will be omitted.
1 and 2 show the principle of a mirror of a projection optical system according to the present invention. FIG. 1 is a yz plan view with the x axis as a reference point, and FIG. 2 is an xy plan view with the z axis as a reference point. . In FIG.
An arbitrary point A on the z-axis is set as a projection point, and a tilt optical system in which an image of the projector unit 3 passing through this projection point A is formed on an image forming surface (plane MN). That is, the surface MN is inclined with respect to the optical axis 7 passing through the projection point A and the midpoint K of the surface MN, and the angle formed by the extension line of the line segment MN and the z axis is the tilt angle. Then, the mirror 10 is provided between the projection point A and the surface MN.
To place. The mirror 10 has a projection point A as a center of curvature (focus point), passes through an x-axis that is an intersection of the y-axis and the z-axis, and approaches a line segment MQ that bisects the inclination angle θ 3 (curved surface). M 1 N 1 ) and a part of this paraboloid, that is, a curved surface M 1 N 1 between the point M 1 on the line segment AM and the point N 1 on the line segment AN, the projection from the projection point A All the light (image light) is reflected in parallel with the z-axis to form an image on the curved surface M 2 N 2 . In addition, in FIG. 2, the point A on the z-axis is the projection point, and the mirror 10 is centered on the projection point A on the z-axis and is arbitrary on the line segment M 1 N 1 on the y-axis. Concentric circles passing through points (arc M 11
It is a curved parabolic surface continuous from M 12 to arc N 11 N 12 .

【0010】このような投影光学系では、面MNの傾角
θ3の自由度が大きいため、装置全体のより一層の薄型
化を図ることができるとともに、ミラー10の放物面
(曲面M11)によって投射点Aからの投射光(画像
光)を全てz軸と平行な同じ向きに反射するので、ミラ
ー10の反射光を結像される曲面M22に入射角差が生
じることなく全て一定の角度で入射させることができ
る。このため、ミラー10による結像面である曲面M2
2とほぼ一致するような位置に透過型スクリーン2を
配置すれば、この透過型スクリーン2に反射光が一定の
角度で入射することになるので、良好な画像を得ること
ができる。In such a projection optical system, since the inclination angle θ 3 of the surface MN has a high degree of freedom, the entire apparatus can be made thinner, and the parabolic surface (curved surface M 1 N) of the mirror 10 can be achieved. Since 1 ) all the projection light (image light) from the projection point A is reflected in the same direction parallel to the z-axis, an incident angle difference occurs on the curved surface M 2 N 2 on which the reflected light of the mirror 10 is imaged. Instead, they can all be incident at a constant angle. Therefore, the curved surface M 2 which is the image plane formed by the mirror 10 is formed.
If the transmissive screen 2 is arranged at a position that substantially coincides with N 2 , the reflected light will enter the transmissive screen 2 at a constant angle, so that a good image can be obtained.

【0011】ところで、この投影光学系では、ミラー1
0による実際の結像部が曲面M22であるため、焦点深
度と歪曲について吟味する必要がある。そこで、このこ
とをミラー10により曲面M22に結像させる画像が対
角40インチ(長辺:短辺=4:3)になる場合の具体
例について説明する。この具体例では、面MNの傾角θ
3を43.5°とし、線分MNの延長線と線分ANとの
なす角α(この角αはチルト角に変わるものである。)
を77°とする。そして、図1におけるミラー10の放
物面の長さを、線分M22がほぼ対角40インチの短辺
の長さ610mmと一致するように選択する。また、チ
ルト角は、自由に選択できるが、図1の線分M22が結
像サイズと一致するように選択する。そこで、図3に示
すように、曲面M22と線分M22との距離が最大とな
る点R、点Sを結ぶ線分RSの中点Tを通り、線分M2
2に平行な直線を線分UVとする。すると、ミラー1
0で反射された光は線分UVに対して約49°の角度で
入射する。この線分UVと曲面M22との距離の差は最
大で25mm程度であり、この線分UV上に透過型スク
リーン2を配置すれば、焦点深度はまず問題にならな
い。また、歪曲については、最大で4%程度の歪曲であ
るから、ほとんど問題にならないが、対称形のレンズを
介在させて歪曲補正を行なってもよい。なお、図2に示
すx−y平面上においても同様である。By the way, in this projection optical system, the mirror 1
Since the actual image forming portion with 0 is the curved surface M 2 N 2, it is necessary to examine the depth of focus and the distortion. Therefore, a specific example in which the image formed on the curved surface M 2 N 2 by the mirror 10 has a diagonal of 40 inches (long side: short side = 4: 3) will be described. In this specific example, the inclination angle θ of the surface MN
3 is set to 43.5 °, and an angle α formed by the extension line of the line segment MN and the line segment AN (this angle α changes to a tilt angle).
Is 77 °. Then, the length of the parabolic surface of the mirror 10 in FIG. 1 is selected so that the line segment M 2 N 2 substantially matches the length 610 mm of the short side having a diagonal of 40 inches. Although the tilt angle can be freely selected, it is selected so that the line segment M 2 N 2 in FIG. 1 matches the image formation size. Therefore, as shown in FIG. 3, the line segment M 2 passes through the midpoint T of the line segment RS connecting the points R and S where the distance between the curved surface M 2 N 2 and the line segment M 2 N 2 is maximum.
A straight line parallel to N 2 is a line segment UV. Then mirror 1
The light reflected at 0 is incident on the line segment UV at an angle of about 49 °. The difference in distance between this line segment UV and the curved surface M 2 N 2 is about 25 mm at maximum, and if the transmissive screen 2 is arranged on this line segment UV, the depth of focus is not a problem. As for the distortion, since it is about 4% at maximum, there is almost no problem, but the distortion may be corrected by interposing a symmetrical lens. The same applies to the xy plane shown in FIG.

【0012】また、このような投影光学系では、線分U
Vを含む疑似的な結像面に入射する光はその法線に対し
て一定の入射角41°で入射するが、実際には透過型ス
クリーン2の入射面の法線に対して入射角0°で入射す
ることが望ましいため、図4に示すような入射角補正手
段であるマイクロプリズムレンズ11によって入射角を
補正している。マイクロプリズムレンズ11は、その入
射面11aが平面に形成され、出射側にマイクロプリズ
ム12が鋸歯状に形成され、入射面11aが図3におけ
る線分UV上に配置されるようになっている。この場
合、マイクロプリズムレンズ11はアクリルなどによっ
て形成されており、ここでは屈折率nが1.49の材質
を採用している。また、マイクロプリズム12のピッチ
Pは、プロジェクタユニット3の液晶表示パネルの画素
ピッチによって設定されている。さらに、マイクロプリ
ズム12の出射面12aの傾斜角は、マイクロプリズム
レンズ11の屈折率n、およびその入射面11aに対す
る光の入射角によって設定されている。In such a projection optical system, the line segment U
The light incident on the pseudo image plane including V enters at a constant incident angle of 41 ° with respect to its normal line, but in reality, the incident angle is 0 with respect to the normal line of the incident plane of the transmissive screen 2. Since it is desirable that the incident light is incident at an angle of °, the incident angle is corrected by the micro prism lens 11 which is an incident angle correcting means as shown in FIG. The micro-prism lens 11 has an incident surface 11a formed into a flat surface, a micro-prism 12 formed in a sawtooth shape on the emission side, and the incident surface 11a is arranged on the line segment UV in FIG. In this case, the micro prism lens 11 is made of acrylic or the like, and here, a material having a refractive index n of 1.49 is adopted. The pitch P of the micro prisms 12 is set by the pixel pitch of the liquid crystal display panel of the projector unit 3. Further, the inclination angle of the emission surface 12a of the micro prism 12 is set by the refractive index n of the micro prism lens 11 and the incident angle of light with respect to the incident surface 11a.

【0013】このようなマイクロプリズムレンズ11で
は、図4に示すように、入射面11aに光が入射角41
°で入射すると全て屈折角26°で屈折され、この屈折
された光がマイクロプリズム12の出射面12aに入射
角36°で入射して屈折角62°で出射するので、出射
光は全て入射面11aに対して垂直となる。したがっ
て、マイクロプリズムレンズ11の出射側(図4では右
側)にマイクロプリズムレンズ11の入射面11aと平
行に透過型スクリーン2を配置すれば、マイクロプリズ
ムレンズ11から出射された光は全て透過型スクリーン
2に入射角0°で入射することになるため、透過型スク
リーン2での配光分布が良くなり、良好な画像を得るこ
とができる。In such a micro-prism lens 11, as shown in FIG. 4, light is incident on the incident surface 11a at an incident angle 41.
When incident at an angle of °, all are refracted at a refraction angle of 26 °, and this refracted light is incident on the emission surface 12a of the microprism 12 at an incident angle of 36 ° and exits at a refraction angle of 62 °, so all the emitted light is at the incident surface. It is perpendicular to 11a. Therefore, if the transmissive screen 2 is arranged on the exit side (the right side in FIG. 4) of the microprism lens 11 in parallel with the incident surface 11a of the microprism lens 11, all the light emitted from the microprism lens 11 is transmitted. Since the light is incident on No. 2 at an incident angle of 0 °, the light distribution on the transmissive screen 2 is improved and a good image can be obtained.

【0014】なお、上記実施例では、入射角補正手段と
してマイクロプリズムレンズ11を用いたが、これに限
らず、例えばマイクロプリズム12の機能を有するレン
チキュラレンズを用いても良い。また、上記実施例で
は、チルト光学系に適用した場合について述べたが、こ
れに限らず、例えばノーマル光学系を採用した投影光学
系にも適用することができる。In the above embodiment, the micro prism lens 11 is used as the incident angle correcting means, but the present invention is not limited to this, and a lenticular lens having the function of the micro prism 12 may be used. Further, in the above embodiment, the case where the invention is applied to the tilt optical system has been described, but the invention is not limited to this, and the invention can be applied to a projection optical system that adopts a normal optical system, for example.

【0015】[0015]

【発明の効果】以上説明したように、この発明によれ
ば、ミラーが画像投影手段からの画像の光を全て同じ向
きに反射する曲面に形成されているので、ミラーで反射
された光をスクリーンに対して入射角差が生じることな
く全て一定の角度で入射させることができ、このためス
クリーンに良好な画像を投影することができる。As described above, according to the present invention, since the mirror is formed on the curved surface that reflects all the light of the image from the image projection means in the same direction, the light reflected by the mirror is screened. The incident light can be incident at a constant angle without causing a difference in the incident angle, and thus a good image can be projected on the screen.

【図面の簡単な説明】[Brief description of drawings]

【図1】この発明の投影光学系のミラーの原理を示すy
−z平面図。FIG. 1 shows the principle of a mirror of a projection optical system according to the present invention.
-Z plan view.

【図2】図1のx−y平面図。2 is an xy plan view of FIG. 1. FIG.

【図3】図1の結像部の拡大図。FIG. 3 is an enlarged view of the image forming unit in FIG.

【図4】マイクロプリズムレンズの要部を示す拡大図。FIG. 4 is an enlarged view showing a main part of a micro prism lens.

【図5】従来の投影型画像表示装置の概略構成図。FIG. 5 is a schematic configuration diagram of a conventional projection-type image display device.

【図6】図5におけるノーマル光学系のミラーの原理
図。6 is a principle diagram of a mirror of a normal optical system in FIG.

【図7】従来のチルト光学系のミラーの原理図。FIG. 7 is a principle diagram of a mirror of a conventional tilt optical system.

【符号の説明】[Explanation of symbols]

1 本体装置 2 透過型スクリーン 3 プロジェクタユニット 7 光軸 10 ミラー 11 マイクロプリズムレンズ 1 Main Unit 2 Transmissive Screen 3 Projector Unit 7 Optical Axis 10 Mirror 11 Micro Prism Lens

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 画像投影手段からの画像をスクリーンに
拡大投影する投影光学系において、 前記画像投影手段からの画像の光を前記スクリーンに向
けて全て同じ向きに反射する曲面に形成されたミラーを
備えたことを特徴とする投影光学系。1. A projection optical system for enlarging and projecting an image from an image projecting means onto a screen, wherein a mirror formed on a curved surface that reflects the light of the image from the image projecting means toward the screen all in the same direction. A projection optical system characterized by being provided. 【請求項2】 前記ミラーと前記スクリーンとの間に
は、前記ミラーで反射された光の前記スクリーンに対す
る入射角を補正する入射角補正手段が介在されているこ
とを特徴とする請求項1記載の投影光学系。2. The incident angle correction means for correcting the incident angle of the light reflected by the mirror with respect to the screen is interposed between the mirror and the screen. Projection optics.
JP23076393A 1993-08-25 1993-08-25 Projection optical system Expired - Lifetime JP3475456B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP23076393A JP3475456B2 (en) 1993-08-25 1993-08-25 Projection optical system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP23076393A JP3475456B2 (en) 1993-08-25 1993-08-25 Projection optical system

Publications (2)

Publication Number Publication Date
JPH0764045A true JPH0764045A (en) 1995-03-10
JP3475456B2 JP3475456B2 (en) 2003-12-08

Family

ID=16912886

Family Applications (1)

Application Number Title Priority Date Filing Date
JP23076393A Expired - Lifetime JP3475456B2 (en) 1993-08-25 1993-08-25 Projection optical system

Country Status (1)

Country Link
JP (1) JP3475456B2 (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006184775A (en) * 2004-12-28 2006-07-13 Fujinon Corp Reflection optical system and projection type display device using same

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006184775A (en) * 2004-12-28 2006-07-13 Fujinon Corp Reflection optical system and projection type display device using same

Also Published As

Publication number Publication date
JP3475456B2 (en) 2003-12-08

Similar Documents

Publication Publication Date Title
US6808271B1 (en) Projection type display apparatus
US7281805B2 (en) Projection-type display apparatus
US7460301B2 (en) Image display apparatus, and transmissive screen and reflecting mirror used for same
CA1240862A (en) Distortion correction for an overhead projector system
JP2002057963A (en) Display device
JP2003177320A (en) Reflection type image formation optical system and projector
US20050168797A1 (en) Image projecting apparatus
US20060092511A1 (en) Image display apparatus, as well as, Fresnel lens sheet and screen to be used therein
JPH09218379A (en) Wide viewing angle liquid crystal projection lens system
JPH03213840A (en) Rear projection type screen and rear projection type image display device using it
US4765733A (en) Light projector
US5146365A (en) Screen and image display apparatus which minimizes the effects of re-reflected incident light
JP2007011154A (en) Screen and image display device using the same
US6652105B1 (en) Reflective light valve-based multimedia projector employing a patterned-silvered mirror
JP2003029149A (en) Projection optical system, display device using the system, picture processor having the device
JP2011175293A (en) Image display apparatus, and fresnel lens sheet and screen used for the image display apparatus
JP3475456B2 (en) Projection optical system
JP2659542B2 (en) Rear projection type projection TV
JPH04107521A (en) Oblique projection type display device
US7798654B2 (en) Image display apparatus
JPH04348333A (en) Projection type display device
JP2006018140A (en) Optical system and rear projection type display apparatus
JPH09203881A (en) Projection type display device
JPH06186496A (en) Projection type picture display device
JPS6392179A (en) Video projector

Legal Events

Date Code Title Description
FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20070926

Year of fee payment: 4

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20080926

Year of fee payment: 5

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20090926

Year of fee payment: 6

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20100926

Year of fee payment: 7

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20100926

Year of fee payment: 7

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20110926

Year of fee payment: 8

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20120926

Year of fee payment: 9

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20130926

Year of fee payment: 10

EXPY Cancellation because of completion of term