JP4409669B2 - Optical waveform shaping device - Google Patents

Description

によって表される。ここで、ｘ₁はスリットの長手方向に垂直な方向の座標であり、ｘ₁＝０がスリットの中心位置である。
【００３８】
光がこのスリットを通過するとフラウンホーファー回折が生じ、このとき、スリットから距離ｌだけ離れた面上での回折パターンの強度分布は、
【数２】

となる。ここで、Ａ₀＝１．０、ａ＝４０（μｍ）、ｌ＝１．０（ｍ）、λ＝７９０（ｎｍ）とすると、その（２）式による回折パターンは図５（ａ）のようになる。
【００３９】
また、幅がａであるスリットがそれぞれ中心間隔ｃだけ離れてＮ個配置された場合、光強度がＡ₀である平行光を入射させたときのスリット位置での光の振幅分布Ｕ₁（ｘ₁）は、次の（３）式
【数３】

によって表される。この場合、回折パターンの強度分布は、
【数４】

となる。ここで、Ｎ＝４、ａ＝４０（μｍ）、ｃ＝１４０（μｍ）、ｌ＝１．０（ｍ）、λ＝７９０（ｎｍ）とすると、（４）式による回折パターンは図５（ｂ）のようになる。すなわち、スリットを複数とすることによって、図５（ａ）のパターンに対して干渉の効果が重畳される。
【００４０】
また、Ｎ＝４、ａ＝１５（μｍ）、ｃ＝１４０（μｍ）、ｌ＝１．０（ｍ）、λ＝７９０（ｎｍ）とすると、（４）式による回折パターンは図５（ｃ）のようになる。すなわち、スリットの幅を狭めることによって、回折の影響が大きくなるために分布の幅が広がり、その結果さらに多くの干渉縞が発生してしまう。なお、スリットの数が増えると各干渉縞の幅が狭くなる。
【００４１】
図２に示す空間光変調器３における透明電極３７の電極パターンは、上記したように図４に示す凹凸形状を有し、これによって、変調される光の一部に対して所定の間隔で形成された複数のスリットと同様の効果を生じる。
【００４２】
この場合、電極パターンのウェッジ部分で生じた回折パターンの１次以上の回折光成分に光の強度の例えば３割程度を奪われてしまい、変調制御の対象となる出力光である０次光の強度が低減されてしまう。また、１次以上の回折光が０次光にノイズ光として重畳してしまうため、波形に余分な変形を生じて望む波形が精度良く得られないという問題がある。回折光強度は、例えば電極部３７ａに対する溝部３７ｂを小さくすることによって低減させることができるが、隣接する電極間の短絡を生じる恐れがあるため、それによって上記の回折光の問題を解決することはできない。
【００４３】
これに対して、本実施例による図２に示す空間光変調器３においては、透明電極３７の液晶層３４側の面上に誘電体層３６が形成されている。この誘電体層３６は透明電極３７とほぼ等しい屈折率を有する材質によって、図４に示すように透明電極３７側（図中の下側）において透明電極３７の溝部３７ｂを埋めるとともに、液晶層３４側（図中の上側）の表面が平坦になるように形成される。
【００４４】
例えば、屈折率１．８０を有する酸化インジウムＩｎ₂Ｏ₃に酸化スズＳｎＯ₂を５．０ｗｔ％添加した材料を膜厚７５ｎｍ程度に蒸着して形成された透明電極３７に対して、その液晶層３４側に屈折率１．８０を有するようにＣｅＯ₂にＣｅＦ₃を２０ｗｔ％添加した材料を膜厚１μｍ程度に蒸着し、溝部３７ｂが埋まるとともに液晶層３４側の表面が平坦になるように研磨することによって誘電体層３６が形成される。また、スピナーを用いて誘電体層３６を塗布しても良い。
【００４５】
このとき、ほぼ同等の屈折率を有する透明電極３７及び誘電体層３６が全体として、液晶層３４側及び透明基板３８側の両面が平坦な層として透過する光に対して作用する。したがって、透明電極３７の電極パターンによる凹凸形状が光に対してスリットのように作用することがなくなって、回折光の発生を抑制することができる。このような空間光変調器３を用いることによって、回折光による出力光の強度減少と、波形整形された波形の望む波形からの乱れ・精度低下とを抑制して、精度の良い効率的な波形整形が可能な光波形整形装置を実現することができる。
【００４６】
なお、透明電極３７及び誘電体層３６の材質及びそれらの屈折率については、それぞれの光波形整形装置の構成において、得られる出力光の光強度、波形精度に対して必要とされる強度・精度を充分に確保できるように回折光の発生が低減・抑制される範囲で、好適な近い（ほぼ同等な）屈折率を有するものを用いれば良い。特に、両者の屈折率を一致させた場合には透明電極３７の電極パターンによる凹凸形状が存在しない場合と等価となり、回折光の発生を回避することができる。
【００４７】
図２〜図４に示す構成からなる空間光変調器３を位相変調用の空間光変調器３ａ及び強度変調用の空間光変調器３ｂとして適用した場合の、図１に示す光波形整形装置による波形整形について説明する。
【００４８】
空間光変調器３ａ及び３ｂは、いずれも図３に示した透明電極３７の電極パターンを構成しているそれぞれの電極部３７ａの長手方向を図１において紙面に対して垂直な方向とし、したがって透明電極３７の各電極による分割の方向が紙面に対して平行な方向となるように設置される。このとき、透明電極３７の電極パターンは平行方向に分光されて入力されている入力光の各波長成分に対応して分割されており、これらの分割された複数の電極部３７ａにそれぞれ所定の電圧を印加することによって、各電極部３７ａの範囲に対応する光の各波長成分ごとに所定の変調が加えられる。
【００４９】
なお、本実施形態においては光波形整形装置への入射光の偏光方向は紙面に対して平行とされ、空間光変調器３ａ及び３ｂは、位相変調用の空間光変調器３ａは液晶分子の配向方向が光の偏光方向に対して平行となるように、また、強度変調用の空間光変調器３ｂは液晶分子の配向方向が光の偏光方向に対して４５度傾くようにそれぞれ配置されている。配向方向を光の偏光方向に対して４５度傾かせた場合には偏波面が回転するので、偏光ビームスプリッター５を用いて紙面に対して平行な方向の偏光方向のみを選択することによって光の振幅・強度を変調することができる。
【００５０】
本発明による光波形整形装置は、上記した実施形態に限られるものではなく、様々な変形・構成の変更が可能である。例えば、分光手段についてはグレーティングに限られず分光プリズムなどを用いても良い。また、結像手段についても凹面鏡に限られず単レンズ、シリンドリカルレンズ、円筒凹面鏡などを用いても良い。
【００５１】
結像手段に凹面鏡または単レンズを用いた場合には、分光される方向に対して垂直な方向について光が集光される。このとき、光強度が増加するにつれて液晶層などの光変調材料層に熱が蓄積されるために目的とする変調を得られなくなる場合がある。このような場合には円筒凹面鏡またはシリンドリカルレンズを用いることによって垂直方向については集光を行わずに光強度を空間的に分散させて、上記した熱の蓄積の問題を回避することができ、高強度の光を波形整形することも可能となる。
【００５２】
空間光変調器の配置等については、図１に示す実施形態においては位相変調用及び強度変調用の２つの空間光変調器を別個に設置して位相変調と強度変調とを独立に制御しているが、例えば１つの空間光変調器のみによる構成として変調を行っても良く、または３つ以上の空間光変調器を配置しても良い。また、位相変調用及び強度変調用など、空間光変調器を複数段に重ねたものを用いて位相変調及び強度変調を独立に制御する構成とすることも可能である。
【００５３】
また、光の偏光方向の制御・選択等については、空間光変調器の入力光及び出力光の光路上などにそれぞれ所定の偏光子を設置し、それらの組み合わせによって制御・選択を行っても良い。
【００５４】
例えば、強度変調に関しては、空間光変調器の入力光または出力光のいずれか一方に対して、その偏波面が液晶分子の配向方向に対してほぼ４５度傾けられた第１の偏光子を設置し、他方に対して、その偏波面が第１の偏光子の偏波面に対してほぼ直交するか、またはほぼ平行な第２の偏光子を設置する構成としても良い。
【００５５】
また、位相変調に関しては、空間光変調器の入力光または出力光のいずれか一方に対して、その偏波面が液晶分子の配向方向に対してほぼ平行な第１の偏光子を設置し、他方に対して、その偏波面が第１の偏光子の偏波面に対してほぼ平行な第２の偏光子を設置する構成としても良い。
【００５６】
また、空間光変調器の構成についても図２、図３に示すものに限られず、様々な変形が可能である。例えば、入力側透明基板３１の入力面または出力側透明基板３８の出力面上に反射防止膜を形成して、さらに光の利用効率を向上しても良い。また、透明電極３７の電極パターンについても図３に示すものに限らず、行いたい変調の内容や入力される光の分光条件等に応じて様々な電極パターンを用いても良い。また、もう一方の透明電極３２に電極パターンを有して構成しても良い。その場合、透明電極３２の液晶層３４側の面上にも同様にほぼ同等の屈折率を有する誘電体層をさらに形成することによって、回折光の発生を抑制することができる。
【００５７】
【発明の効果】
本発明による光波形整形装置は、以上詳細に説明したように、次のような効果を得る。すなわち、光の変調による波形整形に電気アドレス方式の透過型空間光変調器を用い、その透明電極における電極パターンの凹凸形状に対して、凹凸形状を埋めて平坦化させるほぼ屈折率の等しい誘電体層を形成する。これによって、光の透過に対しては透明電極層と誘電体層とが全体として、両面が平坦な層のように作用するので、凹凸形状による回折光の発生に起因する波形整形の効率及び精度の低下を抑制することが可能となる。
【００５８】
電気アドレス方式の空間光変調器を適用した光波形整形装置は、その構造によってコンピュータによるプログラム制御等が可能かつ容易であり、このような構成による光波形整形装置の高効率化・高精度化を実現することによって、入射光に対して様々な光波形への整形・制御が可能となるとともに、光波形の選択性・機能性が大幅に向上される。
【図面の簡単な説明】
【図１】本発明に係る光波形整形装置の一実施形態を示す構成図である。
【図２】図１に示す光波形整形装置において用いられる空間光変調器の一実施例を示す構成図である。
【図３】空間光変調器における透明電極の電極パターンを示す平面図である。
【図４】電極パターンによる凹凸形状を示す拡大断面図である。
【図５】スリットによる回折パターンを示すグラフである。
【図６】従来の光波形整形装置の一例を示す構成図である。
【図７】光パルスに対する位相変調の一例を示すグラフである。
【図８】図７に示す位相変調による光パルスのパルス列への波形整形を示すグラフである。
【符号の説明】
１…グレーティング、２ａ、２ｂ、２ｃ、２ｄ…凹面鏡、４…グレーティング、５…偏光ビームスプリッター、
３、３ａ、３ｂ…空間光変調器、３１…入力側透明基板、３２…透明電極、３３…配向層、３４…液晶層、３４ａ、３４ｂ…スペーサ、３５…配向層、３６…誘電体層、３７…透明電極、３７ａ…電極部、３７ｂ…溝部、３８…出力側透明基板。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical waveform shaping device for shaping an optical waveform.
[0002]
[Prior art]
In recent years, for example, in a laser apparatus, it has been studied to use a spatial light modulator for shaping a light waveform such as a femtosecond light pulse. In waveform shaping by incorporating a spatial light modulator into an optical system, the spatial light modulator can be program-controlled by a computer or the like. Therefore, waveform shaping is facilitated and shaping into various optical waveforms is possible. Control becomes possible.
[0003]
FIG. 6 shows an example of a conventional optical waveform shaping device using a spatial light modulator. This apparatus is configured using a reflective spatial light modulator 8, and incident light (coherent light) to be subjected to waveform shaping is split by the grating 6 and input to the spatial light modulator 8 via the concave mirror 7a. Then, after the waveform is shaped, the light is again superimposed by the grating 9 through the concave mirror 7b, and the light shaped by the total reflection mirror 10 is emitted in a predetermined optical axis direction.
[0004]
7 and 8 show specific examples of waveform shaping by such an optical waveform shaping device. The incident light is a light pulse of a Ti: sapphire laser having a pulse width of 64 fs, a center wavelength of 789.57 nm, a spectral width of 12.59 nm, and a light intensity of 200 mW, and phase modulation shown in FIG. 7 is applied thereto. At this time, a single pulse optical pulse as shown in the time waveform of FIG. 8A is converted into a pulse train (measured by the cross-correlation method) composed of a plurality of optical pulses having different delay times as shown in FIG. 8B. Waveform shaping.
[0005]
[Problems to be solved by the invention]
As an example of the waveform shaping as described above, there is an electric address type transmissive spatial light modulator in which a predetermined electrode pattern is formed on a transparent electrode. However, in such a spatial light modulator, there is a problem in that a concavo-convex shape exists in the transparent electrode layer due to the electrode pattern formed, and diffracted light is generated in the output light due to the influence of the wedge portion of such a pattern shape. is there. When diffracted light is generated, (1) a part of the amount of light is taken away by the diffracted light, so that the amount and intensity of light that is used effectively decreases. (2) The diffracted light is output. Problems with efficiency of waveform shaping, such as being unable to obtain a desired waveform with high accuracy, are superimposed on light as noise light.
[0006]
The present invention has been made in view of the above problems, and provides an optical waveform shaping device capable of performing waveform shaping with high efficiency and accuracy while suppressing generation of diffracted light by the electrode pattern of the spatial light modulator. The purpose is to do.
[0007]
[Means for Solving the Problems]
In order to achieve such an object, an optical waveform shaping device according to the present invention is an optical waveform shaping device that shapes and emits a waveform of incident light, and includes (1) a light modulation material layer and a light modulation material layer. A transmission type spatial light modulator that has two transparent electrode layers formed on the input side and the output side, respectively, and performs waveform shaping of light by modulation, and (2) incidence targeted for waveform shaping Spectroscopic means for spectrally splitting the light, and (3) imaging means for imaging the incident light split by the spectroscopic means on the spatial light modulator, and (4) the spatial light modulator includes the transparent electrode layer. A predetermined electrode pattern for electrical addressing is formed on at least one of the electrodes, and a refractive index substantially equal to that of the transparent electrode layer is provided on the surface of the transparent electrode layer on which the electrode pattern is formed on the light modulation material layer side. The light modulation material layer side surface covering the transparent electrode layer Characterized in that it comprises a are flatly formed dielectric layer.
[0008]
In an electrical addressing type transmissive spatial light modulator applied to an optical waveform shaping device, as described above, the concave and convex grooves formed by the electrode pattern of the transparent electrode are filled and the surface on the light modulation material layer side is flattened. By forming the dielectric layer with a material having a refractive index substantially equal to that of the transparent electrode, the transparent electrode layer and the dielectric layer as a whole act as a flat layer on both sides with respect to transmitted light. As a result, the generation of diffraction due to the uneven shape is reduced and avoided, and the waveform shaping with high efficiency and accuracy can be achieved in which the intensity drop of the outgoing light after waveform shaping and the waveform disturbance are suppressed.
[0009]
Regarding the material of the transparent electrode layer and the dielectric layer and their refractive indexes, the intensity and accuracy required for the optical intensity and waveform accuracy of the output light to be obtained are sufficient in each optical waveform shaping device configuration. As long as the generation of diffracted light is reduced so that it can be ensured, those having substantially the same refractive index can be appropriately selected and used.
[0010]
The spectroscopic means is preferably configured to have a prism or a grating. The imaging means preferably includes a single lens, a cylindrical lens, a concave mirror, or a cylindrical concave mirror.
[0011]
In addition, the spatial light modulator is arranged with the light modulation material layer sandwiched between the input side and the output side with respect to the light modulation material layer, and a transparent electrode layer is formed on the surface of the light modulation material layer side, respectively. It further has two support substrates. Furthermore, at least one of the support substrates may be characterized in that an antireflection film is formed on the surface opposite to the transparent electrode layer.
[0012]
By using a transparent substrate such as a glass face plate that transmits light that is the object of waveform shaping by modulation with high efficiency, the spatial light modulator can be easily and reliably formed, and light can be used efficiently. can do. In particular, the use efficiency of light can be further improved by providing an antireflection film on the outer surface of the support substrate.
[0013]
In addition, one of the transparent electrode layers may be characterized in that the surface on the light modulation material layer side is formed flat.
[0014]
Furthermore, it is preferable that the light modulation material used for the light modulation material layer is a liquid crystal. As the liquid crystal, for example, nematic liquid crystal can be used.
[0015]
In addition, the polarization plane of the input light input from the input side of the spatial light modulator or the output light output from the output side is inclined by approximately 45 degrees with respect to the alignment direction of the liquid crystal molecules in the liquid crystal. The first polarizer is installed.
[0016]
Furthermore, a second polarizer whose polarization plane is substantially orthogonal to the polarization plane of the first polarizer is further installed with respect to the other of the input light or the output light of the spatial light modulator. To do.
[0017]
Alternatively, a second polarizer whose polarization plane is substantially parallel to the polarization plane of the first polarizer with respect to the other of the input light or the output light of the spatial light modulator is further provided. To do.
[0018]
When the polarizer is installed and configured in this way, it is possible to modulate the intensity of the incident light by applying a predetermined voltage between the two transparent electrode layers.
[0019]
The polarization plane of the input light input from the input side of the spatial light modulator or the output light output from the output side is substantially parallel to the alignment direction of the liquid crystal molecules in the liquid crystal. 1 polarizer is installed, It is characterized by the above-mentioned.
[0020]
Furthermore, a second polarizer whose polarization plane is substantially parallel to the polarization plane of the first polarizer is further installed with respect to the other of the input light or the output light of the spatial light modulator. To do.
[0021]
When polarizers are installed and configured in this way, it is possible to apply a predetermined voltage between two transparent electrode layers to perform phase modulation of incident light. Various waveform shapings can be realized by these intensity modulation, phase modulation, and combinations thereof.
[0022]
Further, the spatial light modulators may be stacked in a plurality of stages so that intensity modulation and phase modulation of incident light can be controlled independently. As a result, the control of waveform shaping is further facilitated, and the applicable waveform application range is widened.
[0023]
Further, the optical system may further include a magnifying optical system for enlarging the beam diameter of incident light to be subjected to waveform shaping. Thereby, the wavelength resolution of the incident light on the spatial light modulator can be improved.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of an optical waveform shaping device according to the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted. Further, the dimensional ratios in the drawings do not necessarily match those described.
[0025]
FIG. 1 is a configuration diagram showing an embodiment of an optical waveform shaping device according to the present invention. As incident light to be subjected to waveform shaping by this apparatus, coherent light from a laser apparatus, for example, an optical pulse from a Ti: sapphire laser having a pulse width of 64 fs, a center wavelength of 789.57 nm, a spectral width of 12.59 nm, and an optical intensity of 200 mW is used. The incident light is spectrally separated by the grating 1 which is a spectroscopic means having a predetermined configuration, for example, 600 grooves / mm and a blaze wavelength of 800 nm, and then image forming means. Is input to the first spatial light modulator 3a for waveform shaping while being imaged by the concave mirror 2a. In the present embodiment, the spatial light modulator 3a is used for phase modulation of input light.
[0026]
At this time, the input light to the spatial light modulator 3a is spectrally (Fourier-transformed) in the parallel direction with respect to the paper surface of FIG. 1 by the above-described grating 1, and thus input in the parallel direction of the spatial light modulator 3a. Each wavelength (frequency) component of the incident light is input to the part as input light that is spectrally separated.
[0027]
The light phase-modulated by the spatial light modulator 3a for phase modulation is transferred to the second spatial light modulator 3b for waveform shaping by the concave mirror 2b and the concave mirror 2c of the imaging means, and the case of the spatial light modulator 3a. Similarly, an image is formed and inputted in a state of being dispersed in the parallel direction. This spatial light modulator 3b is used for intensity modulation of input light.
[0028]
In order to improve the wavelength resolution on the spatial light modulators 3a and 3b, the incident light is expanded by a predetermined magnifying optical system (not shown) so that the beam diameter becomes, for example, about 1 cm.
[0029]
The output light that has been modulated and shaped by the spatial light modulator 3a for phase modulation and the spatial light modulator 3b for intensity modulation is incident on the grating 4 via the concave mirror 2d, and each wavelength component is again directed to the same optical axis. After being superimposed (inverse Fourier transform), the light passes through the polarization beam splitter 5 and is finally output as the output light having a waveform-shaped shape.
[0030]
FIG. 2 is a configuration diagram showing an example of the spatial light modulator 3 used as the spatial light modulators 3a and 3b in the optical waveform shaping device shown in FIG. This spatial light modulator 3 is a transmission type in which one side is an input side to which light is input and the other side is an output side from which light is output. In FIG. 2, light is input from the left side in the figure, and from the right side. Modulated and transmitted light is output.
[0031]
The spatial light modulator 3 is formed such that a liquid crystal layer 34 that is a light modulation material layer is sandwiched between an input side transparent substrate 31 and an output side transparent substrate 38 that are support substrates on both sides thereof. As the transparent substrates 31 and 38, for example, glass face plates that efficiently transmit light are used. Further, for example, nematic liquid crystal is used as the liquid crystal layer 34 and is arranged and fixed by the alignment layers 33 and 35 and the spacers 34a and 34b, and the liquid crystal molecules are aligned in a predetermined direction.
[0032]
Transparent electrodes 32 and 37 are formed on the surfaces of the input side transparent substrate 31 and the output side transparent substrate 38 on the liquid crystal layer 34 side (inside in the drawing), respectively. The transparent electrodes 32 and 37 are preferably layers made of an ITO film. For example, a material obtained by adding 5.0 wt% of tin oxide SnO ₂ to indium oxide In ₂ O ₃ having a refractive index of 1.80 is deposited to a thickness of about 75 nm. To form. A dielectric layer 36 is further formed on the surface of the transparent electrode 37 on the liquid crystal layer 34 side.
[0033]
A predetermined voltage is applied between the transparent electrodes 32 and 37, thereby controlling the state of the liquid crystal layer 34 to modulate light. In this embodiment, the transparent electrode 32 on the input side transparent substrate 31 side is for a common ground, and is formed with a uniform film thickness. On the other hand, the transparent electrode 37 on the output side transparent substrate 38 side is formed to have a predetermined electrode pattern composed of a plurality of electrodes. With the above configuration, the voltage applied to each of these electrodes is changed at each part. An electric address type transmissive spatial light modulator 3 is configured to control the light modulation.
[0034]
FIG. 3 is a plan view showing a configuration example of the electrode pattern of the transparent electrode 37 described above in the spatial light modulator 3. In the electrode pattern of the present embodiment, each electrode portion 37a is alternately divided from the upper and lower sides in FIG. 3 into a predetermined number such as 128, for example, in which the horizontal direction in the drawing is divided and the vertical direction is the longitudinal direction. -It is formed with the number of divisions. Each electrode part 37a is electrically separated by a groove part 37b on which no ITO film is deposited.
[0035]
A sectional structure of such an electrode pattern is shown in FIG. 4 in which a part of the dielectric layer 36, the transparent electrode 37, and the transparent substrate 38 is enlarged. The transparent electrode 37 has a concavo-convex shape as shown in FIG. 4 due to the electrode part 37a and the groove part 37b of the electrode pattern, and this causes an effect like a slit to the transmitted modulated light.
[0036]
Here, the diffraction effect (Fraunhofer region) generated by the slit will be described. First, in the case of a single slit whose opening width is a, the light amplitude distribution U ₁ (x ₁ ) at the slit position when collimated light whose light intensity is A ₀ is incident is given by (1 ) Formula [0037]
[Expression 1]

Represented by Here, x ₁ is a coordinate in a direction perpendicular to the longitudinal direction of the slit, and x ₁ = 0 is the center position of the slit.
[0038]
When light passes through this slit, Fraunhofer diffraction occurs, and at this time, the intensity distribution of the diffraction pattern on the surface away from the slit by the distance l is
[Expression 2]

It becomes. Here, if A ₀ = 1.0, a = 40 (μm), l = 1.0 (m), and λ = 790 (nm), the diffraction pattern according to the equation (2) is as shown in FIG. It becomes like this.
[0039]
In addition, when N slits each having a width a are spaced apart by a center interval c, the light amplitude distribution U ₁ (x) at the slit position when the parallel light having the light intensity A ₀ is incident. ₁ ) is the following formula (3):

Represented by In this case, the intensity distribution of the diffraction pattern is
[Expression 4]

It becomes. Here, if N = 4, a = 40 (μm), c = 140 (μm), l = 1.0 (m), and λ = 790 (nm), the diffraction pattern according to the equation (4) is shown in FIG. It becomes like b). That is, by providing a plurality of slits, the interference effect is superimposed on the pattern of FIG.
[0040]
Further, assuming that N = 4, a = 15 (μm), c = 140 (μm), l = 1.0 (m), and λ = 790 (nm), the diffraction pattern according to the equation (4) is shown in FIG. )become that way. That is, by narrowing the width of the slit, the influence of diffraction increases, so the width of the distribution increases, and as a result, more interference fringes are generated. As the number of slits increases, the width of each interference fringe becomes narrower.
[0041]
The electrode pattern of the transparent electrode 37 in the spatial light modulator 3 shown in FIG. 2 has the concavo-convex shape shown in FIG. 4 as described above, and is thereby formed at a predetermined interval with respect to a part of the modulated light. This produces the same effect as the plurality of slits.
[0042]
In this case, for example, about 30% of the light intensity is deprived by the first-order or higher-order diffracted light component of the diffraction pattern generated at the wedge portion of the electrode pattern, and the 0th-order light that is the output light to be modulated is controlled. Strength will be reduced. In addition, since the first-order or higher-order diffracted light is superimposed on the zero-order light as noise light, there is a problem that a desired waveform cannot be obtained with high accuracy due to excessive deformation of the waveform. The diffracted light intensity can be reduced by, for example, reducing the groove portion 37b with respect to the electrode portion 37a, but there is a possibility of causing a short circuit between adjacent electrodes, thereby solving the above-mentioned problem of diffracted light. Can not.
[0043]
In contrast, in the spatial light modulator 3 shown in FIG. 2 according to the present embodiment, the dielectric layer 36 is formed on the surface of the transparent electrode 37 on the liquid crystal layer 34 side. The dielectric layer 36 is made of a material having a refractive index substantially equal to that of the transparent electrode 37, and fills the groove 37b of the transparent electrode 37 on the transparent electrode 37 side (lower side in the figure) as shown in FIG. The side (upper side in the figure) surface is formed to be flat.
[0044]
For example, the liquid crystal layer is formed on the transparent electrode 37 formed by depositing a material in which 5.0 wt% of tin oxide SnO ₂ is added to indium oxide In ₂ O ₃ having a refractive index of 1.80 to a thickness of about 75 nm. A material obtained by adding 20 wt% of CeF ₃ to CeO ₂ so as to have a refractive index of 1.80 on the 34th side is deposited to a thickness of about 1 μm, and polished so that the groove 37b is filled and the surface on the liquid crystal layer 34 side is flattened. Thus, the dielectric layer 36 is formed. Alternatively, the dielectric layer 36 may be applied using a spinner.
[0045]
At this time, the transparent electrode 37 and the dielectric layer 36 having substantially the same refractive index as a whole act on light transmitted through both the liquid crystal layer 34 side and the transparent substrate 38 side as flat layers. Therefore, the uneven shape due to the electrode pattern of the transparent electrode 37 does not act like a slit on the light, and the generation of diffracted light can be suppressed. By using such a spatial light modulator 3, it is possible to suppress a decrease in the intensity of the output light due to the diffracted light and a disturbance / decrease in accuracy of the waveform-shaped waveform from a desired waveform, thereby achieving an accurate and efficient waveform. An optical waveform shaping device capable of shaping can be realized.
[0046]
In addition, about the material of the transparent electrode 37 and the dielectric material layer 36, and those refractive indexes, the intensity | strength and precision required with respect to the light intensity and waveform accuracy of the output light obtained in the structure of each optical waveform shaping device As long as the generation of diffracted light is reduced / suppressed, a material having a suitable close (substantially equivalent) refractive index may be used. In particular, when the refractive indexes of the two are matched, this is equivalent to the case where there is no uneven shape due to the electrode pattern of the transparent electrode 37, and generation of diffracted light can be avoided.
[0047]
When the spatial light modulator 3 having the configuration shown in FIGS. 2 to 4 is applied as the spatial light modulator 3a for phase modulation and the spatial light modulator 3b for intensity modulation, the optical waveform shaping device shown in FIG. Waveform shaping will be described.
[0048]
In each of the spatial light modulators 3a and 3b, the longitudinal direction of each electrode portion 37a constituting the electrode pattern of the transparent electrode 37 shown in FIG. 3 is set to a direction perpendicular to the paper surface in FIG. The electrode 37 is installed so that the direction of division by each electrode is parallel to the paper surface. At this time, the electrode pattern of the transparent electrode 37 is divided corresponding to each wavelength component of the input light that is split and input in the parallel direction, and a predetermined voltage is applied to each of the divided electrode portions 37a. Is applied to each wavelength component of the light corresponding to the range of each electrode part 37a.
[0049]
In the present embodiment, the polarization direction of the incident light to the optical waveform shaping device is parallel to the paper surface, and the spatial light modulators 3a and 3b are the phase modulation spatial light modulators 3a are aligned liquid crystal molecules. The spatial light modulator 3b for intensity modulation is arranged so that the orientation direction of the liquid crystal molecules is inclined by 45 degrees with respect to the polarization direction of the light so that the direction is parallel to the polarization direction of the light. . When the orientation direction is tilted by 45 degrees with respect to the polarization direction of the light, the polarization plane rotates. Therefore, by using the polarization beam splitter 5 to select only the polarization direction parallel to the paper surface, Amplitude and intensity can be modulated.
[0050]
The optical waveform shaping device according to the present invention is not limited to the above-described embodiment, and various modifications and configuration changes are possible. For example, the spectral means is not limited to a grating, and a spectral prism or the like may be used. The imaging means is not limited to a concave mirror, and a single lens, a cylindrical lens, a cylindrical concave mirror, or the like may be used.
[0051]
When a concave mirror or a single lens is used as the image forming means, light is collected in a direction perpendicular to the direction in which light is split. At this time, as the light intensity increases, heat may be accumulated in the light modulation material layer such as a liquid crystal layer, so that the target modulation may not be obtained. In such a case, by using a cylindrical concave mirror or cylindrical lens, the light intensity can be spatially dispersed without focusing in the vertical direction, and the above problem of heat accumulation can be avoided. It is also possible to shape the waveform of intense light.
[0052]
With regard to the arrangement of the spatial light modulator, in the embodiment shown in FIG. 1, two spatial light modulators for phase modulation and intensity modulation are separately installed, and phase modulation and intensity modulation are controlled independently. However, for example, the modulation may be performed by using only one spatial light modulator, or three or more spatial light modulators may be arranged. It is also possible to employ a configuration in which phase modulation and intensity modulation are independently controlled using a plurality of spatial light modulators stacked in a plurality of stages, such as for phase modulation and intensity modulation.
[0053]
In addition, for the control / selection of the polarization direction of light, a predetermined polarizer may be installed on the optical path of the input light and output light of the spatial light modulator, and the control / selection may be performed by a combination thereof. .
[0054]
For example, with respect to intensity modulation, a first polarizer whose polarization plane is inclined by approximately 45 degrees with respect to the alignment direction of the liquid crystal molecules is provided for either input light or output light of the spatial light modulator. On the other hand, a configuration may be adopted in which a second polarizer whose polarization plane is substantially orthogonal to or substantially parallel to the polarization plane of the first polarizer may be provided.
[0055]
For phase modulation, a first polarizer whose polarization plane is substantially parallel to the alignment direction of the liquid crystal molecules is provided for either input light or output light of the spatial light modulator, and the other On the other hand, a second polarizer whose polarization plane is substantially parallel to the polarization plane of the first polarizer may be installed.
[0056]
Also, the configuration of the spatial light modulator is not limited to that shown in FIGS. 2 and 3, and various modifications can be made. For example, an antireflection film may be formed on the input surface of the input side transparent substrate 31 or the output surface of the output side transparent substrate 38 to further improve the light utilization efficiency. Also, the electrode pattern of the transparent electrode 37 is not limited to that shown in FIG. 3, and various electrode patterns may be used according to the content of modulation to be performed, the spectral condition of input light, and the like. The other transparent electrode 32 may have an electrode pattern. In that case, the generation of diffracted light can be suppressed by further forming a dielectric layer having a substantially equivalent refractive index on the surface of the transparent electrode 32 on the liquid crystal layer 34 side.
[0057]
【The invention's effect】
As described in detail above, the optical waveform shaping device according to the present invention provides the following effects. In other words, a dielectric material with substantially the same refractive index that uses a transmissive spatial light modulator of the electrical address system for waveform shaping by light modulation, and fills and flattens the uneven shape of the electrode pattern in the transparent electrode. Form a layer. As a result, the transparent electrode layer and the dielectric layer as a whole act as a flat layer for light transmission, so the efficiency and accuracy of waveform shaping due to the generation of diffracted light due to the uneven shape. Can be suppressed.
[0058]
The optical waveform shaping device to which the electrical addressing spatial light modulator is applied is easy and easy to program control by a computer due to its structure, and the optical waveform shaping device with this configuration is highly efficient and accurate. By realizing it, it becomes possible to shape and control the incident light into various optical waveforms, and the selectivity and functionality of the optical waveform are greatly improved.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an embodiment of an optical waveform shaping device according to the present invention.
2 is a block diagram showing an embodiment of a spatial light modulator used in the optical waveform shaping device shown in FIG.
FIG. 3 is a plan view showing an electrode pattern of a transparent electrode in the spatial light modulator.
FIG. 4 is an enlarged cross-sectional view showing an uneven shape by an electrode pattern.
FIG. 5 is a graph showing a diffraction pattern by a slit.
FIG. 6 is a block diagram showing an example of a conventional optical waveform shaping device.
FIG. 7 is a graph showing an example of phase modulation with respect to an optical pulse.
8 is a graph showing waveform shaping of an optical pulse into a pulse train by the phase modulation shown in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Grating, 2a, 2b, 2c, 2d ... Concave mirror, 4 ... Grating, 5 ... Polarizing beam splitter,
3, 3a, 3b ... spatial light modulator, 31 ... input side transparent substrate, 32 ... transparent electrode, 33 ... alignment layer, 34 ... liquid crystal layer, 34a, 34b ... spacer, 35 ... alignment layer, 36 ... dielectric layer, 37 ... Transparent electrode, 37a ... Electrode part, 37b ... Groove part, 38 ... Output side transparent substrate.

Claims (16)

An optical waveform shaping device for shaping and emitting the waveform of incident light,
A transmissive spatial light modulator having a light modulation material layer and two transparent electrode layers formed on the input side and the output side with respect to the light modulation material layer, and performing waveform shaping of light by modulation; ,
A spectroscopic means for splitting the incident light to be subjected to waveform shaping;
Imaging means for forming an image on the spatial light modulator with the incident light split by the spectroscopic means,
The spatial light modulator is configured by forming a predetermined electrode pattern for an electrical address on at least one of the transparent electrode layers, and the light modulation material layer of the transparent electrode layer on which the electrode pattern is formed And a dielectric layer having a refractive index substantially equal to that of the transparent electrode layer and having a flat surface on the light modulation material layer side so as to cover the transparent electrode layer. Optical waveform shaping device. 2. The optical waveform shaping device according to claim 1, wherein the spectroscopic means includes a prism or a grating. 3. The optical waveform shaping device according to claim 1, wherein the imaging unit includes a single lens, a cylindrical lens, a concave mirror, or a cylindrical concave mirror. The spatial light modulator is disposed on the input side and the output side of the light modulation material layer with the light modulation material layer interposed therebetween, and the transparent electrode layer is formed on the surface of the light modulation material layer side. The optical waveform shaping device according to any one of claims 1 to 3, further comprising two support substrates formed respectively. 5. The optical waveform shaping device according to claim 4, wherein an antireflection film is formed on at least one of the support substrates on a surface opposite to the transparent electrode layer. 6. The optical waveform shaping device according to claim 1, wherein the transparent electrode layer has a flat surface on the light modulation material layer side. The optical waveform shaping device according to claim 1, wherein the light modulation material used for the light modulation material layer is a liquid crystal. The polarization plane of the input light input from the input side of the spatial light modulator or the output light output from the output side is approximately 45 with respect to the alignment direction of the liquid crystal molecules in the liquid crystal. 8. The optical waveform shaping device according to claim 7, wherein a first polarizer tilted at a predetermined angle is installed. A second polarizer whose polarization plane is substantially orthogonal to the polarization plane of the first polarizer with respect to the other of the input light or the output light of the spatial light modulator; 9. The optical waveform shaping device according to claim 8, wherein A second polarizer having a plane of polarization substantially parallel to the plane of polarization of the first polarizer with respect to the other of the input light or the output light of the spatial light modulator; 9. The optical waveform shaping device according to claim 8, wherein The optical waveform shaping device according to any one of claims 8 to 10, wherein intensity modulation of the incident light is performed by applying a predetermined voltage between the two transparent electrode layers. The polarization plane of the input light input from the input side of the spatial light modulator or the output light output from the output side is substantially parallel to the alignment direction of the liquid crystal molecules in the liquid crystal. 8. The optical waveform shaping device according to claim 7, further comprising a first polarizer. A second polarizer having a plane of polarization substantially parallel to the plane of polarization of the first polarizer with respect to the other of the input light or the output light of the spatial light modulator; The optical waveform shaping device according to claim 12, characterized in that: The optical waveform shaping device according to claim 12 or 13, wherein a predetermined voltage is applied between the two transparent electrode layers to perform phase modulation of the incident light. 15. The structure according to claim 1, wherein the spatial light modulator is configured to be able to independently control intensity modulation and phase modulation of the incident light by overlapping the spatial light modulators in a plurality of stages. The optical waveform shaping device according to one item. The optical waveform shaping device according to claim 1, further comprising a magnifying optical system for enlarging a beam diameter of the incident light to be subjected to waveform shaping.

Images