JP2004204538A - Road-sign display system and road-sign display method in tunnel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To display a road sign having an excellent visibility, inhibiting the height of a tunnel. <P>SOLUTION: A laser irradiator 11, a convex lens 12 and a diffraction optical element 10 are installed so as to be suspended from the ceiling surface of the tunnel 2. The luminous flux of laser beams irradiated from the laser irradiator 11 is widened by the lens 12, and projected to the element 10 as reproduced illuminating light 13. The diffraction optical element recording interference fringes while using the scattered light from a road sign board for a substance as body light is used as the diffraction optical element 10, the road sign as a reproduced image (20r or 20i) is displayed in the tunnel 2 by receiving reproduced illuminating light 13. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

【００３０】
ここで、ｇ(x,y)は道路標識３８の座標(x,y)における画像情報を表している。つまり、平面波を受けた道路標識３８が、その平面波を反射することによって得られる道路標識３８の平面状における画像情報である。また、数１式において、k=2π/λであり、λは光の波長である。
【００３１】
一方、点光源３９から照射される参照光３４を収束球面波として考えると、この参照光３４の振幅は、数２式で表される。
【００３２】
【数２】

【００３３】
ここでｒは点光源３９と乾板面との間の距離をあらわしている。
【００３４】
そして、乾板面の光強度は、物体光と参照光との光強度を加え合わせたものであるから、乾板面上の光強度は、数３式で表される。
【００３５】
【数３】

0
【００３６】
数３式は、乾板面上の座標(xi,yi)上での光強度を表している。つまり、このI(xi,yi)が、乾板面上に現れる干渉縞の式である。
【００３７】
これら数１式から数３式に従ってコンピュータで光強度を計算し、その結果を高精度のプリンター（例えば印刷用のイメージセッター）やレーザ直接描画装置で透明フィルムやガラス基板に露光する。レーザ直接描画装置とはガラス基板に例えばフォトレジスト等の光感光性材料を塗り、その上に先ほどの計算結果に従って小さく絞ったレーザ光線で直接干渉縞を描画していくものである。
【００３８】
このように、コンピュータを利用することによって干渉縞を算出し、透明フィルムやガラス基板に干渉縞を描画することにより、回折光学素子が作成されるのである。
【００３９】
＜再生像の形成＞
次に、上記のような方法で作成された回折光学素子を利用して、再生像を形成する方法について説明する。図５に示すように、レーザ照射装置１１から照射されたレーザ光線が凸レンズ１２を経由したのち、回折光学素子１０に照射される。これにより、例えば図に示すような位置に虚像２０ｉあるいは実像２０ｒが形成される。ここで、回折光学素子１０を作成したときの参照光と同じ波面で再生像を形成した場合には、回折光学素子１０のレーザ照射装置側に虚像２０ｉが形成される。一方、参照光に対して複素共役である波面で再生像を形成すると回折光学素子１０のレーザ照射装置と反対側に実像２０ｒが形成される。
【００４０】
以上のような方法により、回折光学素子を作成し、回折光学素子を図２で示したように、トンネル２内に設置することにより、再生像として道路標識を表示することが可能である。本発明によれば、従来の道路標識板よりも高さの小さな回折光学素子を利用して道路標識の標示を行なうことができ、トンネル高さを低くすることが可能である。
【００４１】
ここで、回折光学素子の大きさが、実物の道路標識板と比較して小さくなると、回折光学素子によって再生される像の視野角は、実物の道路標識板を見る場合と比べて狭くなることになるが、回折光学素子によって再生される実像２０ｒは、図２にも示したように、回折光学素子１０の配置位置よりも、自動車１側に近い場所で結像されるので、視認性が良い。これにより、実物の道路標識板と比べてサイズの小さい回折光学素子を利用しながらも、視認性に優れた道路標識を表示することが可能である。
【００４２】
なお、図２で示したようなシステム構成であれば、道路標識として虚像２０ｉを再生させた場合には、虚像２０ｉの結像位置が運転者から遠くなる。したがって、図２で示したシステム構成であれば、実像２０ｒを再生することが好ましいが、回折光学素子１０を作成する際の物体光の照射方向を調整することにより、あるいは、レーザ照射装置１１による再生照明光の照射角度や、回折光学素子１０の配置角度などを調整することによっては、虚像２０ｉを運転者の視点に近い位置で結像させることも可能である。したがって、原理的には、実像２０ｒおよび虚像２０ｉのいずれを再生する方法でも可能である。
【００４３】
＜変形例＞
上記第１の実施の形態において、光学的に回折光学素子を作成する際、図３に示したように、１つの物体光３７と、１つの参照光３４を利用して、写真乾板３５に干渉縞を記録するようにした。このようにして作成された回折光学素子に再生照明光を照射することによって、１つの再生像（実像２０ｒあるいは虚像２０ｉ）を形成することが可能であった。
【００４４】
これに対して、複数の物体光３７と、１つの参照光３４を利用して、写真乾板３５に干渉縞を記録し、回折光学素子を作成するようにしてもよい。このようにして作成された回折光学素子に、再生照明光を照射すれば、複数の再生像が形成されることになる。
【００４５】
たとえば、２種類の実体の道路標識板を用意し、この２つの道路標識板にレーザ光を照射し、２つの物体光を得る。そして、この２つの物体光を照射して回折光学素子を作成すれば、再生像として２種類の道路標識を表示させることが可能である。
【００４６】
あるいは、同じ道路標識板を２つ用意し、この２つの道路標識板にレーザ光を照射し、２つの物体光を得る。そして、この２つの物体光をそれぞれ異なる角度で照射して回折光学素子を作成する。このようにして作成された回折光学素子に再生照明光を照射することにより、異なる結像位置に、２つの同じ再生像としての道路標識を表示させることが可能である。これを利用すれば、物体光の照射角度を適宜調整することにより、１枚の回折光学素子を利用して、複数位置に同じ道路標識を表示させることが可能となるのである。
【００４７】
｛第２の実施の形態｝
次に、複数の再生像を形成する第２の実施の形態について、図６を参照しながら説明する。
【００４８】
図６は、２つの再生像を形成する道路標識の表示システムを示している。図に示すように、トンネル２の天井側には、２つのレーザ照射装置１１ａ，１１ｂ、および２つの凸レンズ（凹レンズでも良い）１２ａ，１２ｂが吊り下げられるようにして設けられている。ここでは、２つのレーザ照射装置１１ａ，１１ｂが垂直方向に２段に積み重なるような配置となっている。そして、その位置関係に合わせるように、凸レンズ１２ａ，１２ｂも上下２段に積み重ねられるように配置されている。
【００４９】
レーザ照射装置１１ａから照射されたレーザ光は、凸レンズ１２ａで拡大されたのち、再生照明光１３ａとして回折光学素子１０を照明する。これによって、自動車１Ｂの運転者の視線上に実像２２ｒを形成する。一方、レーザ照射装置１１ｂから照射されたレーザ光は、凸レンズ１２ｂで拡大されたのち、再生照明光１３ｂとして回折光学素子１０を照明する。これによって、自動車１Ａの運転者の視線上に実像２１ｒを形成する。なお、ここでは、いずれも実像２１ｒ，２２ｒを再生する場合を例に説明しているが、もちろん、参照光と同じ再生照明光を照射することにより、虚像を再生するようにしてもよい。
【００５０】
このようにして、この道路標識表示システムでは、２つのレーザ照射装置１１ａ，１１ｂと、２つの凸レンズ１２ａ，１２ｂと、１つの回折光学素子１０を利用することにより、２つの再生像を形成することを可能としているのである。
【００５１】
図に示した例において、自動車１Ｂは、自動車１Ａの前方を走行している。そして、実像２１ｒは自動車１Ａの位置からは見ることができるが、自動車１Ｂの位置に移動すると見えなくなる。しかし、このシステムにおいては、複数の実像２１ｒ，２２ｒを空間上に形成させているので、自動車１Ａが移動して自動車１Ｂの位置に移動した場合でも、道路標識の実像２２ｒを参照することができるのである。したがって、２つの像２１ｒ，２２ｒで同じ実像（画像）が形成されるようにしておけば、１つの回折光学素子１０を用いて、トンネルの進行方向において、同じ道路標識を長い期間にわたって表示させることが可能である。
【００５２】
このようなシステムでは、１つの物体光と、１つの参照光とから、干渉縞を記録することにより、回折光学素子１０を作成するようにすればよい。そして、この回折光学素子１０に対して、図に示したように、異なる角度から再生光を照射することにより、２つの再生像を形成することが可能となるのである。
【００５３】
図６で示した実施の形態では、上下にレーザ照射装置１１ａ，１１ｂおよび凸レンズ１２ａ，１２ｂを配置することにより、上下に２つの再生像を形成している例であるが、さらに上下に多くの像またはトンネルの長手方向（奥行き方向）にも複数の像を形成させてどの位置からでも道路標識が見えるようにすることが可能である。
【００５４】
図７は、上下２段、横方向に３つ、計６個の再生像２５，２５・・・を表示させたイメージ図である。このような再生像を形成するためには、回折光学素子１０には、同様に、１つの物体光と、１つの参照光とによって干渉縞を記録すればよく、レーザ照射装置１１および凸レンズを上下２段、横方向に３つ配列するようにすればよい。
【００５５】
｛第３の実施の形態｝
第２の実施の形態で示したシステムではレーザ照射装置を２台利用し、２つの再生像を形成する方法を説明した。次に、１台のレーザ照射装置１１および１つの凸レンズ１２によって、２つの再生像を形成する方法について説明する。
【００５６】
図８に示すように、トンネル２の天井側には、レーザ照射装置１１および凸レンズ１２が吊り下げられるようにして設けられている。そして、この実施の形態では、凸レンズ１２と回折光学素子１０との間に波面変換器１５が設けられている。
【００５７】
このような構成において、レーザ照射装置１１から照射されたレーザ光は、凸レンズ１２を介して波面変換器１５に入射する。そして、波面変換器１５からは、２つの変換光１６ａ，１６ｂが出力される。そして、この２つの変換光１６ａ，１６ｂが再生照明光として回折光学素子１０に入射されることによって、回折光学素子１０は、２つの実像２３ｒ，２４ｒを形成するのである。
【００５８】
波面変換器については図９を参照しながら説明する。波面変換器は、光の波面を異なる光の波面に変換するものである。例えば平面波を球面波に変換することや、１つの球面波を複数の球面波に変換することが可能である。
【００５９】
図８では波面変換器１５から２つの球面波が生じている状態を示している。この波面変換器１５により出力される光で回折光学素子１０を照明すると、図６で示した場合と同様に複数の再生像を形成することが可能である。
【００６０】
波面変換器の作成方法について説明する。波面変換器の作成方法は、基本的に、回折光学素子１０を作成する方法と同じである。ここではコンピュータを使った計算による方法を示す。図４における道路標識の画像ｇ(x,y)の変わりに、２つの点光源４４，４６を２つの物体とみなす。
【００６１】
図９ではｙ軸上に２つの点光源４４，４６が存在している。また、y軸とは距離ziの間隔を空けて乾板４３が配置されている。さらに、点光源４１が配置され、点光源４１は、乾板面に参照光４２を照射している。ここで、２つの点光源の振幅を表す式は、数４式に示すように、２つの球面波を加えたものとなる。
【００６２】
【数４】

【００６３】
数４式において、ｒ１およびｒ２は２つの点光源４４，４６から乾板面上の座標までの距離を示している。
【００６４】
そして、数５式は、物体光と参照光を加え合わせた光強度をあらわしている。
【００６５】
【数５】

【００６６】
この数４式および数５式に従ってコンピュータで光強度を計算し、その結果を高精度のプリンター（例えば印刷用のイメージセッター）やレーザ直接描画装置で透明フィルムやガラス基板に露光することにより、干渉縞を描画することにより、波面変換器が作成されるのである。
【００６７】
このようにして、作成された波面変換器に再生照明光を照射することにより、光の回折現象によって元の点光源を再生することが可能となり、波面の変換器として作用するのである。
【００６８】
そして、この変換された光を再生照明光として扱うことにより、回折光学素子１０に複数の再生照明光を照射することと同じ効果が得られるので、回折光学素子１０によって、複数の再生像としての道路標識を形成することが可能となるのである。
【００６９】
以上、第３の実施の形態では、波面変換器１５を利用することにより、レーザ照射装置１１および凸レンズ１２の数を削減しつつ、複数の再生像を形成することが可能である。
【００７０】
図８で示した実施の形態では、上下に２つの再生像を示しているが、図７で示した場合と同様に、トンネルの横方向にも複数の像を再生させてどの位置からでも標識を見ることができるようにすることも可能である。この場合、波面変換器を作成する際には、表示する再生像の数に合わせた点光源を用意し、再生像の表示位置に合わせて点光源の配置位置を調整するようにすればよい。
【００７１】
また、上記第１から第３の実施の形態においては、１枚の回折光学素子を使って再生像を形成する実施の形態を示しているが、トンネルの横方向及び長手方向（自動車の進行方向）に複数の回折光学素子を設置し、さらに広い範囲で標識標識を表示させることも可能である。
【００７２】
なお、上記第１から第３の実施の形態において、回折光学素子は、トンネルの天井面に吊り下げられるように設けられているが、必ずしも天井面から吊り下げられる必要はなく、トンネル側壁から所定の部材で支持し、天井面から下方に向けて配置されるようにしてもよい。
【００７３】
【発明の効果】
以上説明したように、請求項１から請求項８に記載の発明では、トンネル天井面に吊り下げられた回折光学素子を利用して道路標識を表示させるので、回折光学素子の配置位置よりも、観察者に近い位置で道路標識を再生像として結像させることが可能である。したがって、従来の実物の道路標識板と比べてサイズの小さい回折光学素子を利用した場合でも、視認性のよい道路標識を表示することが可能であり、トンネル高さを低くすることが可能である。
【００７４】
請求項２または請求項６に記載の発明では、１つの再生照明光を利用して複数の道路標識を再生像として形成することが可能であり、異なる種類の道路標識を複数形成させることや、同じ道路標識を複数の位置に形成させることが可能である。
【００７５】
請求項３または請求項７に記載の発明では、複数の再生照明光を利用して複数の道路標識を再生像として形成するので、単一の物体光を利用して作成された回折光学素子を用いながらトンネル内の複数位置に道路標識を形成させることが可能である。
【００７６】
請求項４または請求項８に記載の発明では、波面変換器を利用して、複数の再生照明光を生成するので、単一の照射装置と、単一の物体光を利用して作成された回折光学素子を用いながらトンネル内の複数位置に道路標識を形成させることが可能である。
【図面の簡単な説明】
【図１】トンネル内に設置された回折光学素子の位置を示す図である。
【図２】第１の実施の形態にかかる道路標識表示システムの全体図である。
【図３】回折光学素子を光学的に作成する方法を示す図である。
【図４】回折光学素子に記録する干渉縞を計算機を用いて算出する場合の空間配置図である。
【図５】回折光学素子を利用して表示された道路標識の実像および虚像を示す図である。
【図６】第２の実施の形態にかかる道路標識表示システムの全体図である。
【図７】上下左右に複数の再生像として道路標識を表示させたイメージ図である。
【図８】第３の実施の形態にかかる道路標識表示システムの全体図である。
【図９】波面変換器の作成方法を示す図である。
【図１０】従来の実物の道路標識の配置状態を示す図である。
【符号の説明】
２ トンネル
１０ 回折光学素子
１１ レーザ照射装置
１２ 凸レンズ
１３ 再生照明光
２０ｉ 虚像
２０ｒ 実像
３１ レーザ照射装置
３２ ハーフミラー
３３，３６ 凸レンズ
３４ 参照光
３５ 写真乾板
３７ 物体光
３８ （実物）道路標識板[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a configuration of a system for displaying a road sign in a tunnel and a display method thereof.
[0002]
[Technical background and problems to be solved by the invention]
Various road signs are installed on general roads and highways. For example, at an intersection, the names of places and roads in each direction are displayed. And these road signs may be installed in a tunnel.
[0003]
FIG. 10 is a diagram showing a conventional example in which a road sign is installed in a tunnel. FIG. 10A is a cross-sectional view of the tunnel 102, and FIG. 10B is a cross-sectional view of the tunnel 102. A road sign 100 is installed so as to hang from the ceiling surface of the tunnel 102.
[0004]
The size of the road sign 100 in the height direction varies, but even a small one usually has a size of about 1.2 m. The height that the tunnel 102 needs to secure in order for the automobile 101 to travel is usually about 4.5 m. Therefore, the height required for the tunnel 102 is 5.7 m or more.
[0005]
As described above, conventionally, in tunnel construction, it was necessary to make the height 5.7 m or more. This means increasing the amount of tunnel excavation work to secure the height of the road sign, and was an issue to be improved. In particular, considering that the place where the road sign is installed in the tunnel is only a small part of the width of the road and the length of the road, taking into account Is inefficient.
[0006]
Therefore, an object of the present invention is to provide a road sign with good visibility while making it possible to reduce the height of the tunnel as compared with the related art.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the present invention uses a small optical element having a small size in the height direction and optically displays a road sign as a reproduced image in a space in a tunnel.
[0008]
The invention according to claim 1 is a system for displaying a road sign in a tunnel, wherein the diffractive optical element is suspended from a ceiling surface of the tunnel, and the diffractive optical element is reconstructed and illuminated in the tunnel. Irradiating means for irradiating light, wherein the diffractive optical element diffracts the reproduction illumination light incident by interference fringes recorded on the dry plate surface, thereby displaying a road sign as a reproduction image. Features.
[0009]
According to a second aspect of the present invention, in the road sign display system according to the first aspect, the diffractive optical element has interference fringes recorded by a plurality of object lights and one reference light, and the incident light is incident on the diffractive optical element. A plurality of road signs are displayed as a reproduced image by diffracting the reproduction illumination light.
[0010]
The invention according to claim 3 is a system for displaying a road sign in a tunnel, wherein the diffractive optical element suspended on a ceiling surface of the tunnel and a different angle with respect to the diffractive optical element in the tunnel. A plurality of irradiating means for irradiating a plurality of reproduction illumination light from the light source, wherein the diffractive optical element diffracts the plurality of reproduction illumination light incident from the plurality of irradiation means by interference fringes recorded on a dry plate surface thereof. Thus, a plurality of road signs are displayed as a reproduced image.
[0011]
The invention according to claim 4 is a system for displaying a road sign in a tunnel, comprising: an irradiating means for irradiating illumination light in the tunnel; and a wavefront conversion for converting the incident illumination light into a plurality of reproduction illumination lights. Means, and a diffractive optical element suspended from the ceiling surface of the tunnel and receiving a plurality of reproduction illumination lights emitted from the wavefront converting means, wherein the diffractive optical element is recorded on its dry plate surface. A plurality of road signs are displayed as a reproduced image by diffracting the plurality of reproduction illumination lights incident from the wavefront converting means by interference fringes.
[0012]
The invention according to claim 5 is a method for displaying a road sign in a tunnel, wherein a step of recording interference fringes on a photographic dry plate to form a diffractive optical element and the step of hanging the ceiling on a ceiling surface of the tunnel. The method includes a step of irradiating the diffractive optical element with reproduction illumination light and a step of forming a road sign as a reproduced image by the diffractive optical element.
[0013]
The invention according to claim 6 is a method for displaying a road sign in a tunnel, comprising recording interference fringes on a photographic plate with a plurality of object lights and one reference light to form a diffractive optical element. Irradiating the diffractive optical element suspended on the ceiling surface of the tunnel with reproduction illumination light; and forming a plurality of road signs as a plurality of reproduced images by the diffractive optical element. It is characterized by.
[0014]
The invention according to claim 7 is a method for displaying a road sign in a tunnel, wherein interference fringes are recorded on a photographic plate to form a diffractive optical element, and wherein the step is suspended on a ceiling surface of the tunnel. The method includes the steps of: irradiating a plurality of reproduction illumination lights to the diffractive optical element at different incident angles; and forming a plurality of road signs as a plurality of reproduced images by the diffractive optical element.
[0015]
The invention according to claim 8 is a method for displaying a road sign in a tunnel, wherein a step of recording interference fringes on a first photographic plate and forming a diffractive optical element, and a step of forming interference fringes on a second photographic plate. Recording a wavefront converter, irradiating the wavefront converter provided in the tunnel with illumination light, and converting the illumination light into a plurality of reproduction illumination lights in the wavefront converter. And a step in which the plurality of reconstructed illumination lights are incident on the diffractive optical element suspended on the ceiling surface of the tunnel, and a step of forming a plurality of reconstructed images by the diffractive optical element. It is characterized by.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
<< 1st Embodiment >>
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a road sign display system according to a first embodiment of the present invention. FIG. 1A is a cross-sectional view of a tunnel 2, and FIG. It is.
[0017]
As described above, the tunnel 2 needs to have a height of 4.5 m in order to secure the traveling of the car 1. In the present embodiment, since the diffractive optical element 10 is installed so as to be suspended from the ceiling surface of the tunnel 2, the height of the tunnel 2 is set to 4.5 m for securing the traveling of the automobile 1. It is necessary to add the height of the optical element 10 to the height.
[0018]
By making the height of the diffractive optical element 10 lower than that of a conventional road sign board, in the present embodiment, it is possible to make the tunnel height lower than before. For example, in the example shown in the figure, since the height of the diffractive optical element 10 is 30 cm, the height of the tunnel 2 can be 4.8 m. The configuration of the road sign display system using the diffractive optical element 10 will be described later in detail. However, as a general rule, a road sign is reproduced (a real image or a virtual image) by applying a laser beam to the diffractive optical element 10. And formed on the space.
[0019]
FIG. 2 shows an overall view of a road sign display system for forming a reproduced image. A laser irradiation device 11, a convex lens 12 (may be a concave lens), and a diffractive optical element 10 are provided so as to be suspended from the ceiling surface of the tunnel 2. Although not shown, the convex lens 12 is also suspended from the ceiling surface of the tunnel 2 by a predetermined frame or the like.
[0020]
The laser beam emitted from the laser irradiator 11 is refracted by the convex lens 12, and then the luminous flux of the laser beam is expanded and irradiates the diffractive optical element 10. As a result, a road sign is formed as a reproduced image in the space.
[0021]
Note that the reproduced image is formed as a real image or a virtual image by an optical system when the diffractive optical element 10 is created. More specifically, if a reproduced image is formed by using the same wavefront as the reference light used when producing the diffractive optical element 10, the diffractive optical element 10 can be illuminated with a laser irradiation device. On the other hand, a virtual image 20i is formed on the side of the diffractive optical element 10, and a real image 20r is formed on the front side of the diffractive optical element 10 (on the side opposite to the laser irradiation device 11 with respect to the diffractive optical element 10). That is, from the viewpoint 3 of the driver running in the automobile 1, a virtual image 20i is formed on the back side of the diffractive optical element 10, and a real image 20r is formed on the front side of the diffractive optical element 10.
[0022]
<Creation of diffractive optical element>
Two methods for producing the diffractive optical element 10 will be described. The two methods are a method of optically creating a diffractive optical element and a method of creating a diffractive optical element from a result obtained by calculation using a computer.
[0023]
First, an optical method will be described with reference to FIG. The laser beam irradiated from the laser irradiation device 31 is divided into two directions by a half mirror 32. Of the light split in two directions by the half mirror, the transmitted light passes through the convex lens 33 and the reflected light passes through the convex lens 36, thereby expanding the light flux of each light.
[0024]
The transmitted light passing through the convex lens 33 directly illuminates the photographic plate 35. This light is referred to as reference light 34. The light reflected by the other convex lens 36 illuminates an object, here, a road sign board 38 (that is, a signboard) which is a substance. Then, the photographic dry plate 35 is irradiated with the scattered light of the light applied to the road sign plate 38. This scattered light is called object light 37. Then, the object light 37 reflected by the object and the reference light 34 emitted from the laser irradiation device 31 interfere on the photographic dry plate 35, and interference fringes are recorded. The dry plate is subjected to development, fixing, bleaching and the like.
[0025]
By using such a method, a reproduced image can be formed by irradiating the photographic dry plate 35 with the interference fringes recorded thereon with the reproduction light. However, since this principle utilizes the light diffraction phenomenon, The element on which the interference fringes are recorded is usually called a diffractive optical element. Thus, the diffractive optical element 10 is created.
[0026]
Next, a method of creating a diffractive optical element from a calculation result by a computer will be described with reference to FIG. This method is not an optical method, but a method of calculating an interference fringe on a dry plate surface by calculating a wavefront of light by a computer.
[0027]
As shown in the drawing, considering the xyz space, it is assumed that the road sign 38 and the dry plate 35 are virtually arranged on a plane perpendicular to the z-axis. The xy axis represents the coordinate axis on the road sign 38 (object), the xi-yi axis represents the coordinate axis on the dry plate 35, and the road sign 38 is a z = 0 plane. The distance between the road sign 38 and the dry plate 35 is defined as zi. Further, a point light source 39 is virtually arranged, and the reference light 34 irradiates the dry plate 35 from the point light source 39.
[0028]
Under such conditions, when the road sign 38 is irradiated with a plane wave parallel to the z-axis, the plane wave hits the road sign 38 and becomes scattered light to reach the plate surface. The amplitude of light on the surface is expressed by Equation 1.
[0029]
(Equation 1)

[0030]
Here, g (x, y) represents image information at the coordinates (x, y) of the road sign 38. That is, the road sign 38 receiving the plane wave is image information in a plane of the road sign 38 obtained by reflecting the plane wave. Further, in Equation 1, k = 2π / λ, and λ is the wavelength of light.
[0031]
On the other hand, assuming that the reference light 34 emitted from the point light source 39 is a convergent spherical wave, the amplitude of the reference light 34 is expressed by Expression 2.
[0032]
(Equation 2)

[0033]
Here, r represents the distance between the point light source 39 and the surface of the dry plate.
[0034]
Since the light intensity on the dry plate surface is the sum of the light intensity of the object light and the light intensity of the reference light, the light intensity on the dry plate surface is expressed by Expression 3.
[0035]
[Equation 3]

0
[0036]
Equation 3 represents the light intensity on the coordinates (xi, yi) on the surface of the dry plate. That is, I (xi, yi) is an expression of interference fringes appearing on the surface of the dry plate.
[0037]
The light intensity is calculated by a computer according to Equations (1) to (3), and the result is exposed on a transparent film or glass substrate by a high-precision printer (for example, an image setter for printing) or a laser direct drawing apparatus. The laser direct writing apparatus is an apparatus which applies a photosensitive material such as a photoresist on a glass substrate and directly draws interference fringes on the glass substrate with a laser beam narrowed down in accordance with the above calculation result.
[0038]
Thus, a diffraction optical element is created by calculating an interference fringe by using a computer and drawing the interference fringe on a transparent film or a glass substrate.
[0039]
<Formation of Reconstructed Image>
Next, a method of forming a reproduced image using the diffractive optical element created by the above method will be described. As shown in FIG. 5, the laser beam emitted from the laser irradiation device 11 passes through the convex lens 12 and then is applied to the diffractive optical element 10. Thereby, for example, a virtual image 20i or a real image 20r is formed at a position as shown in the figure. Here, when a reproduced image is formed on the same wavefront as the reference light when the diffractive optical element 10 was created, a virtual image 20i is formed on the laser irradiation device side of the diffractive optical element 10. On the other hand, when a reproduced image is formed with a wavefront that is complex conjugate to the reference light, a real image 20r is formed on the side of the diffractive optical element 10 opposite to the laser irradiation device.
[0040]
By producing a diffractive optical element by the above-described method and installing the diffractive optical element in the tunnel 2 as shown in FIG. 2, it is possible to display a road sign as a reproduced image. ADVANTAGE OF THE INVENTION According to this invention, a sign of a road sign can be performed using the diffractive optical element whose height is smaller than the conventional road sign board, and it is possible to make tunnel height low.
[0041]
Here, when the size of the diffractive optical element is smaller than that of a real road sign board, the viewing angle of an image reproduced by the diffractive optical element is smaller than that of a real road sign board. However, since the real image 20r reproduced by the diffractive optical element is formed at a position closer to the automobile 1 than the position where the diffractive optical element 10 is arranged as shown in FIG. good. As a result, it is possible to display a road sign excellent in visibility while using a diffractive optical element having a smaller size than a real road sign plate.
[0042]
With the system configuration as shown in FIG. 2, when the virtual image 20i is reproduced as a road sign, the imaging position of the virtual image 20i is far from the driver. Therefore, in the case of the system configuration shown in FIG. 2, it is preferable to reproduce the real image 20 r, but by adjusting the irradiation direction of the object light when creating the diffractive optical element 10, or by using the laser irradiation device 11. The virtual image 20i can be formed at a position close to the driver's viewpoint by adjusting the irradiation angle of the reproduction illumination light, the arrangement angle of the diffractive optical element 10, and the like. Therefore, in principle, any method of reproducing either the real image 20r or the virtual image 20i is possible.
[0043]
<Modification>
In the first embodiment, when an optically diffractive optical element is formed, as shown in FIG. 3, one object light 37 and one reference light 34 are used to interfere with a photographic dry plate 35. The stripes were recorded. By irradiating reproduction illumination light to the diffractive optical element thus formed, one reproduction image (real image 20r or virtual image 20i) can be formed.
[0044]
On the other hand, a plurality of object beams 37 and one reference beam 34 may be used to record interference fringes on the photographic plate 35 to create a diffractive optical element. By irradiating reproduction illumination light to the diffractive optical element thus created, a plurality of reproduced images are formed.
[0045]
For example, two types of actual road sign boards are prepared, and the two road sign boards are irradiated with laser light to obtain two object lights. By irradiating these two object lights to create a diffractive optical element, it is possible to display two types of road signs as reproduced images.
[0046]
Alternatively, two identical road sign boards are prepared, and the two road sign boards are irradiated with laser light to obtain two object lights. Then, the two object beams are irradiated at different angles to form a diffractive optical element. By irradiating reproduction illumination light to the diffractive optical element created in this way, it is possible to display road signs as two identical reproduction images at different imaging positions. If this is used, the same road sign can be displayed at a plurality of positions using one diffractive optical element by appropriately adjusting the irradiation angle of the object light.
[0047]
<< 2nd Embodiment >>
Next, a second embodiment for forming a plurality of reproduced images will be described with reference to FIG.
[0048]
FIG. 6 shows a display system for a road sign forming two reproduced images. As shown in the figure, on the ceiling side of the tunnel 2, two laser irradiation devices 11a and 11b and two convex lenses (or concave lenses) 12a and 12b are provided so as to be suspended. Here, the two laser irradiation devices 11a and 11b are arranged so as to be vertically stacked in two stages. The convex lenses 12a and 12b are also arranged so as to be stacked vertically in two stages so as to match the positional relationship.
[0049]
The laser light emitted from the laser irradiation device 11a is enlarged by the convex lens 12a, and then illuminates the diffractive optical element 10 as reproduction illumination light 13a. Thus, a real image 22r is formed on the line of sight of the driver of the automobile 1B. On the other hand, the laser light emitted from the laser irradiation device 11b is enlarged by the convex lens 12b, and then illuminates the diffractive optical element 10 as reproduction illumination light 13b. Thus, a real image 21r is formed on the line of sight of the driver of the vehicle 1A. Here, the case where both the real images 21r and 22r are reproduced is described as an example, but it is needless to say that the virtual image may be reproduced by irradiating the same reproduction illumination light as the reference light.
[0050]
Thus, in this road sign display system, two reproduced images are formed by using two laser irradiation devices 11a and 11b, two convex lenses 12a and 12b, and one diffractive optical element 10. It is possible.
[0051]
In the example shown in the figure, the automobile 1B is running ahead of the automobile 1A. Then, the real image 21r can be seen from the position of the car 1A, but disappears when moved to the position of the car 1B. However, in this system, since the plurality of real images 21r and 22r are formed in the space, the real image 22r of the road sign can be referred to even when the vehicle 1A moves and moves to the position of the vehicle 1B. It is. Therefore, if the same real image (image) is formed by the two images 21r and 22r, the same road sign can be displayed for a long period in the traveling direction of the tunnel using one diffractive optical element 10. Is possible.
[0052]
In such a system, the diffractive optical element 10 may be created by recording interference fringes from one object beam and one reference beam. By irradiating the diffractive optical element 10 with reproduction light from different angles, as shown in the figure, two reproduction images can be formed.
[0053]
The embodiment shown in FIG. 6 is an example in which two reproduced images are formed vertically by arranging the laser irradiation devices 11a and 11b and the convex lenses 12a and 12b above and below. It is possible to form a plurality of images in the longitudinal direction (depth direction) of the image or the tunnel so that the road sign can be seen from any position.
[0054]
FIG. 7 is an image diagram in which a total of six reproduced images 25, 25,... In order to form such a reproduced image, interference fringes may be similarly recorded on the diffractive optical element 10 by one object light and one reference light, and the laser irradiation device 11 and the convex lens are moved up and down. Two rows and three rows may be arranged in the horizontal direction.
[0055]
<< 3rd Embodiment >>
In the system described in the second embodiment, a method of forming two reproduced images using two laser irradiation devices has been described. Next, a method of forming two reproduced images with one laser irradiation device 11 and one convex lens 12 will be described.
[0056]
As shown in FIG. 8, on the ceiling side of the tunnel 2, a laser irradiation device 11 and a convex lens 12 are provided so as to be suspended. In this embodiment, a wavefront converter 15 is provided between the convex lens 12 and the diffractive optical element 10.
[0057]
In such a configuration, laser light emitted from the laser irradiation device 11 enters the wavefront converter 15 via the convex lens 12. The wavefront converter 15 outputs two converted lights 16a and 16b. The two converted lights 16a and 16b are incident on the diffractive optical element 10 as reproduction illumination light, so that the diffractive optical element 10 forms two real images 23r and 24r.
[0058]
The wavefront converter will be described with reference to FIG. The wavefront converter converts a wavefront of light into a wavefront of different light. For example, it is possible to convert a plane wave into a spherical wave or convert one spherical wave into a plurality of spherical waves.
[0059]
FIG. 8 shows a state where two spherical waves are generated from the wavefront converter 15. When the diffractive optical element 10 is illuminated with the light output from the wavefront converter 15, a plurality of reproduced images can be formed as in the case shown in FIG.
[0060]
A method for creating a wavefront converter will be described. The method of producing the wavefront converter is basically the same as the method of producing the diffractive optical element 10. Here, a calculation method using a computer will be described. Instead of the image g (x, y) of the road sign in FIG. 4, the two point light sources 44 and 46 are regarded as two objects.
[0061]
In FIG. 9, two point light sources 44 and 46 exist on the y-axis. The dry plate 43 is arranged at a distance zi from the y-axis. Further, a point light source 41 is arranged, and the point light source 41 irradiates the reference light 42 to the surface of the dry plate. Here, the expression representing the amplitude of the two point light sources is obtained by adding two spherical waves as shown in Expression 4.
[0062]
(Equation 4)

[0063]
In Equation 4, r1 and r2 indicate the distance from the two point light sources 44 and 46 to the coordinates on the surface of the dry plate.
[0064]
Expression 5 represents the light intensity obtained by adding the object light and the reference light.
[0065]
(Equation 5)

[0066]
The light intensity is calculated by a computer according to equations (4) and (5), and the result is exposed to a transparent film or a glass substrate by a high-precision printer (for example, an image setter for printing) or a laser direct drawing apparatus, thereby causing interference. By drawing the fringes, a wavefront converter is created.
[0067]
By irradiating the created wavefront converter with the reproduction illumination light in this manner, it becomes possible to reproduce the original point light source by the light diffraction phenomenon, and it functions as a wavefront converter.
[0068]
By treating the converted light as reproduction illumination light, the same effect as irradiating the diffractive optical element 10 with a plurality of reproduction illumination lights can be obtained. It is possible to form road signs.
[0069]
As described above, in the third embodiment, by using the wavefront converter 15, it is possible to form a plurality of reproduced images while reducing the numbers of the laser irradiation devices 11 and the convex lenses 12.
[0070]
In the embodiment shown in FIG. 8, two reconstructed images are shown at the top and bottom. However, similar to the case shown in FIG. Can also be seen. In this case, when creating the wavefront converter, point light sources corresponding to the number of reproduced images to be displayed may be prepared, and the arrangement position of the point light sources may be adjusted according to the display position of the reproduced image.
[0071]
Further, in the first to third embodiments, the embodiment in which a reproduced image is formed by using one diffractive optical element is shown, but the lateral direction and the longitudinal direction of the tunnel (the traveling direction of the automobile) are used. It is also possible to install a plurality of diffractive optical elements in (1) and display the sign in a wider range.
[0072]
In the first to third embodiments, the diffractive optical element is provided so as to be hung on the ceiling surface of the tunnel. However, the diffractive optical element does not necessarily have to be hung from the ceiling surface. And may be arranged downward from the ceiling surface.
[0073]
【The invention's effect】
As described above, according to the first to eighth aspects of the present invention, the road sign is displayed using the diffractive optical element suspended from the tunnel ceiling surface, so that the position of the diffractive optical element is more than the position of the diffractive optical element. It is possible to form a road sign as a reproduced image at a position close to the observer. Therefore, even when a diffractive optical element having a smaller size than a conventional real road sign board is used, a road sign with good visibility can be displayed, and the tunnel height can be reduced. .
[0074]
According to the invention described in claim 2 or claim 6, it is possible to form a plurality of road signs as reproduced images by using one reproduction illumination light, and to form a plurality of different types of road signs, The same road sign can be formed at a plurality of positions.
[0075]
According to the third or seventh aspect of the present invention, since a plurality of road signs are formed as a reproduced image by using a plurality of reproduction illumination lights, a diffractive optical element created by using a single object light can be used. It is possible to form road signs at multiple locations in a tunnel while using.
[0076]
In the invention according to claim 4 or claim 8, since a plurality of reconstructed illumination lights are generated by using the wavefront converter, they are created by using a single irradiation device and a single object light. It is possible to form road signs at a plurality of positions in a tunnel while using a diffractive optical element.
[Brief description of the drawings]
FIG. 1 is a diagram showing a position of a diffractive optical element installed in a tunnel.
FIG. 2 is an overall view of a road sign display system according to the first embodiment.
FIG. 3 is a diagram illustrating a method of optically forming a diffractive optical element.
FIG. 4 is a spatial arrangement diagram when an interference fringe to be recorded on a diffractive optical element is calculated using a computer.
FIG. 5 is a diagram showing a real image and a virtual image of a road sign displayed using a diffractive optical element.
FIG. 6 is an overall view of a road sign display system according to a second embodiment.
FIG. 7 is an image diagram in which road signs are displayed as a plurality of reproduced images in the upper, lower, left, and right directions.
FIG. 8 is an overall view of a road sign display system according to a third embodiment.
FIG. 9 is a diagram showing a method of creating a wavefront converter.
FIG. 10 is a diagram showing the arrangement of conventional real road signs.
[Explanation of symbols]
2 tunnel
10 Diffractive optical element
11 Laser irradiation device
12 convex lens
13 Reproduction illumination light
20i virtual image
20r real image
31 Laser irradiation device
32 half mirror
33, 36 convex lens
34 Reference light
35 Photo Dry Plate
37 Object Light
38 (real) road sign board

Claims (8)

A system for displaying a road sign in a tunnel,
A diffractive optical element suspended from the ceiling of the tunnel,
In the tunnel, irradiation means for irradiating the diffraction optical element with reproduction illumination light,
With
The diffractive optical element,
A road sign display system in a tunnel, wherein a road sign as a reproduced image is displayed by diffracting the reproduction illumination light incident by the interference fringes recorded on the dry plate surface. 2. The road sign display system according to claim 1, wherein the diffraction optical element has interference fringes recorded by a plurality of object lights and one reference light, and diffracts the incident reproduction illumination light. A road sign display system in a tunnel, wherein a plurality of road signs are displayed as reproduced images. A system for displaying a road sign in a tunnel,
A diffractive optical element suspended from the ceiling of the tunnel,
In the tunnel, a plurality of irradiation means for irradiating a plurality of reproduction illumination light from different angles with respect to the diffractive optical element,
With
The diffractive optical element,
A road sign in a tunnel characterized by displaying a plurality of road signs as a reproduced image by diffracting the plurality of reproduction illumination lights incident from the plurality of irradiation means by interference fringes recorded on the dry plate surface. Display system. A system for displaying a road sign in a tunnel,
Irradiating means for irradiating illumination light in the tunnel,
Wavefront converting means for converting the incident illumination light into a plurality of reproduction illumination lights,
A diffractive optical element that is suspended from the ceiling of the tunnel and receives a plurality of reconstructed illumination light beams emitted from the wavefront conversion unit,
With
The diffractive optical element,
Road sign display in a tunnel characterized by displaying a plurality of road signs as a reproduced image by diffracting the plurality of reproduction illumination lights incident from the wavefront conversion means by interference fringes recorded on the dry plate surface. system. A method of displaying a road sign in a tunnel,
Recording interference fringes on a photographic plate to create a diffractive optical element;
Irradiating reproduction illumination light to the diffractive optical element suspended on the ceiling surface of the tunnel,
Forming a road sign as a reproduced image by the diffractive optical element,
A road sign display method in a tunnel, comprising: A method of displaying a road sign in a tunnel,
Recording interference fringes on a photographic plate with a plurality of object lights and one reference light to form a diffractive optical element;
Irradiating reproduction illumination light to the diffractive optical element suspended on the ceiling surface of the tunnel,
A step of forming a plurality of road signs as a plurality of reproduced images by the diffractive optical element,
A road sign display method in a tunnel, comprising: A method of displaying a road sign in a tunnel,
Recording interference fringes on a photographic plate to create a diffractive optical element;
Irradiating a plurality of reproduction illumination light at different angles of incidence on the diffractive optical element suspended on the ceiling surface of the tunnel,
A step of forming a plurality of road signs as a plurality of reproduced images by the diffractive optical element,
A road sign display method in a tunnel, comprising: A method of displaying a road sign in a tunnel,
Recording interference fringes on a first photographic plate to form a diffractive optical element;
Recording interference fringes on a second photographic dry plate to create a wavefront transducer;
Irradiating the wavefront converter provided in the tunnel with illumination light,
Converting the illumination light into a plurality of reproduction illumination lights in the wavefront converter;
The plurality of reproduction illumination light is incident on the diffractive optical element suspended on the ceiling surface of the tunnel,
Forming a plurality of reproduced images by the diffractive optical element,
A road sign display method in a tunnel, comprising:

Images