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JP2006322917A - Laser device - Google Patents

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JP2006322917A
JP2006322917A JP2006024456A JP2006024456A JP2006322917A JP 2006322917 A JP2006322917 A JP 2006322917A JP 2006024456 A JP2006024456 A JP 2006024456A JP 2006024456 A JP2006024456 A JP 2006024456A JP 2006322917 A JP2006322917 A JP 2006322917A
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laser
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JP5354707B2 (en
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Tatsuya Ueno
達也 上野
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Azbil Corp
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a laser device capable of executing highly reliable and accurate distance measurement utilizing a self-coupling effect of a laser element regardless of the change of a wavelength changing rate characteristic of the laser element. <P>SOLUTION: Feedback control of a driving condition of the laser element is performed so that a modulated laser light component is kept constant, based on information of the modulated laser light component generated by a self-coupling effect between a wavelength modulated laser light output from the laser element and reflected light from a reference point, set beforehand, of the laser light. For example, a driving current of the laser element is corrected based on a correction coefficient calculated theoretically, or feedback control of an amplitude of the driving current or its period increased and decreased periodically in order to perform wavelength modulation of the laser light is performed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

本発明は、レーザ素子における自己結合効果を利用して計測対象物の状態、例えば計測対象物までの距離や計測対象物の振動・変位等を検出するレーザ装置に関する。   The present invention relates to a laser device that detects a state of a measurement object, for example, a distance to the measurement object, vibration / displacement of the measurement object, and the like using a self-coupling effect in a laser element.

光学的な距離計測技術の1つに半導体レーザ素子の自己結合効果(自己混合効果とも言う)を利用したものがある(例えば特許文献1,2を参照)。この手法は、例えば図1に示すように所定の変調信号を用いて駆動したレーザ素子(LD)1から出力されるレーザ光(出力光)を検出対象物2に向けて照射すると共に、検出対象物2により反射されて前記レーザ素子1に戻ったレーザ光(戻り光)と前記出力光との自己結合効果により生じた干渉信号が重畳した出力光を受光器(PD)3にて受光し、その出力を周波数分析する等して前記検出対象物2までの距離(L)や速度、振動等の状態を測定するものである。   One optical distance measurement technique uses a self-coupling effect (also referred to as a self-mixing effect) of a semiconductor laser element (see, for example, Patent Documents 1 and 2). In this method, for example, as shown in FIG. 1, laser light (output light) output from a laser element (LD) 1 driven using a predetermined modulation signal is irradiated toward the detection target 2 and the detection target is also detected. An output light in which an interference signal generated by a self-coupling effect between the laser light (return light) reflected by the object 2 and returned to the laser element 1 and the output light is superimposed is received by a light receiver (PD) 3, The output is subjected to frequency analysis or the like to measure the distance (L), speed, vibration and the like to the detection object 2.

即ち、レーザ素子1の出力光の発振波長を連続的に変化させると、検出対象物2により反射した戻り光と上記レーザ素子1の出力光とが干渉を生じ、共振条件(強めあう)を満たす波長においてはレーザ素子1の増幅効率が僅かに上がり、また減衰条件(弱めあう)を満たす波長においては増幅効率が僅かに下がり、この結果、受光器3の出力が増減を繰り返す。例えば付与した電流値に応じて出力光の発振波長が変化するタイプのレーザー素子に、三角波形の駆動電流を付与すると、三角波の一周期分において、電流値が時間の経過に比例して連続的に増加し、ピークに達した後に減少する。これに応じてレーザ素子から放出される出力光の波長は連続的に長くなり、ピークに達した後、出力光の波長は連続的に短くなる。   That is, when the oscillation wavelength of the output light of the laser element 1 is continuously changed, the return light reflected by the detection object 2 interferes with the output light of the laser element 1 to satisfy the resonance condition (strengthening). At the wavelength, the amplification efficiency of the laser device 1 is slightly increased, and at the wavelength satisfying the attenuation condition (weakening), the amplification efficiency is slightly decreased. As a result, the output of the light receiver 3 is repeatedly increased and decreased. For example, when a triangular waveform drive current is applied to a laser element whose output light oscillation wavelength changes according to the applied current value, the current value is continuously proportional to the passage of time in one period of the triangular wave. Increases after reaching the peak. In response to this, the wavelength of the output light emitted from the laser element continuously increases, and after reaching the peak, the wavelength of the output light continuously decreases.

このようにして出力光の波長が連続的に増減する中で、上記出力光とその戻り光との間の共振条件および減衰条件が交互に何度も満たされる。この結果、前記受光器3からは図2に示すように上記三角波に微小な干渉成分(共振成分および減衰成分)が重畳した波形が得られる。この干渉成分は、レーザ素子1と検出対象物2との距離L等の情報を含んでいる。従ってこの波形を解析すれば、上記共振成分の周波数から検出対象物2までの距離や速度、振動等の状態を求めることが可能となる。例えば上記変調光を微分して三角波に重畳した信号成分を抽出し、この信号成分を計数することによって検出対象物2の状態を求めることが可能となる。
特開平10−246782号公報 特開平11−287859号公報
Thus, while the wavelength of the output light continuously increases and decreases, the resonance condition and the attenuation condition between the output light and the return light are alternately satisfied many times. As a result, the light receiver 3 obtains a waveform in which minute interference components (resonance component and attenuation component) are superimposed on the triangular wave as shown in FIG. This interference component includes information such as the distance L between the laser element 1 and the detection target 2. Therefore, if this waveform is analyzed, it is possible to obtain the distance, speed, vibration, and other states from the frequency of the resonance component to the detection target 2. For example, the state of the detection target 2 can be obtained by differentiating the modulated light, extracting a signal component superimposed on a triangular wave, and counting the signal component.
JP 10-246782 A JP-A-11-287859

ところでレーザ素子1からの出力光の強度(光量)Pは、その駆動電流Iによって変化し、またその発振波長λも上記駆動電流Iによって変化する。即ち、駆動電流Iの増減によりレーザ素子1に僅かな熱膨張・収縮が生じ、これに伴ってレーザ光の発振波長λが僅かに増減(ドリフト)する。しかもレーザ素子1からの出力光の強度(光量)Pおよび発振波長λは、レーザ素子1の温度Tによっても変化する。するとレーザ素子1から出力されるレーザ光の波長変調帯域が変化し、これに伴ってレーザ素子1における自己結合作用によって生じる干渉成分の周波数も変化する。この結果、上記レーザ光の干渉成分を分析して検出される計測対象物2までの距離にずれが生じると言う問題が生じる。   Incidentally, the intensity (light quantity) P of the output light from the laser element 1 varies with the drive current I, and the oscillation wavelength λ also varies with the drive current I. That is, a slight thermal expansion / contraction occurs in the laser element 1 due to the increase / decrease in the drive current I, and the oscillation wavelength λ of the laser light slightly increases / decreases (drifts) accordingly. Moreover, the intensity (light quantity) P of the output light from the laser element 1 and the oscillation wavelength λ also change depending on the temperature T of the laser element 1. Then, the wavelength modulation band of the laser light output from the laser element 1 changes, and accordingly, the frequency of the interference component generated by the self-coupling action in the laser element 1 also changes. As a result, there arises a problem that the distance to the measurement object 2 detected by analyzing the interference component of the laser beam is shifted.

本発明はこのような事情を考慮してなされたもので、その目的は、レーザ素子の温度ドリフト等に起因する計測誤差を補正して、上記レーザ素子の自己結合効果を利用した距離計測や振動・変位検出等を信頼性良く高精度に実行することのできるレーザ装置を提供することにある。   The present invention has been made in consideration of such circumstances, and its purpose is to correct a measurement error caused by a temperature drift of the laser element, and to perform distance measurement and vibration using the self-coupling effect of the laser element. It is an object of the present invention to provide a laser device that can perform displacement detection and the like with high reliability and high accuracy.

上述した目的を達成するべく本発明に係るレーザ装置は、計測対象物に向けて波長変調したレーザ光を照射すると共に、上記計測対象物にて反射した上記レーザ光が導入される自己結合型のレーザ素子を備え、このレーザ素子におけるレーザ光の自己結合効果により生じた変調レーザ光を分析して前記計測対象物の状態、例えば計測対象物までの距離や計測対象物の振動・変位等を測定するものであって、
予め設定された基準点からの反射光により前記レーザ素子の自己結合効果により生じた変調レーザ光成分の情報に基づいて、該変調レーザ光成分を一定に保つように前記レーザ素子の駆動条件をフィードバック制御する手段を備えたことを特徴としている。
In order to achieve the above-described object, a laser apparatus according to the present invention irradiates a measurement target with wavelength-modulated laser light and introduces the laser light reflected by the measurement target. A laser element is provided, and the modulated laser beam generated by the self-coupling effect of the laser beam in the laser element is analyzed to measure the state of the measurement object, such as the distance to the measurement object and the vibration / displacement of the measurement object. To do,
Based on the information of the modulated laser light component generated by the self-coupling effect of the laser element by the reflected light from the preset reference point, the driving condition of the laser element is fed back so as to keep the modulated laser light component constant. It is characterized by having means for controlling.

ちなみに前記予め設定された基準点は、計測対象領域に検出対象物が存在しない場合における上記計測対象領域の背景面、またはレーザ素子からの出力されたレーザ光の前記計測対象領域に対する入出射面からなる。また前記レーザ素子の駆動条件のフィードバック制御は、例えば前記変調レーザ光成分の周波数が予め設定した周波数となる補正係数を求め、この補正係数に従って前記レーザ素子の駆動条件を補正して行われる。或いは前記レーザ光の波長変調が、前記レーザ素子の駆動電流を周期的に増減させて行われるような場合には、前記レーザ素子の駆動条件のフィードバック制御を、上記駆動電流の振幅または前記駆動電流の増減周期を変化させて行うようにしても良い。   Incidentally, the preset reference point is from the background surface of the measurement target area when no detection target is present in the measurement target area, or the incident / exit plane of the laser beam output from the laser element with respect to the measurement target area. Become. The feedback control of the driving conditions of the laser element is performed, for example, by obtaining a correction coefficient at which the frequency of the modulated laser light component becomes a preset frequency and correcting the driving condition of the laser element according to the correction coefficient. Alternatively, when the wavelength modulation of the laser light is performed by periodically increasing / decreasing the driving current of the laser element, feedback control of the driving condition of the laser element is performed using the amplitude of the driving current or the driving current. The increase / decrease period may be changed.

上述した構成のレーザ装置においては、予め設定された基準点からの反射光による前記レーザ素子の自己結合効果により生じた変調レーザ光成分の情報、具体的には出力光と反射光との干渉成分のビート数や周波数を一定に保つように前記レーザ素子の駆動条件をフィードバック制御するので、仮にレーザ素子に温度ドリフトが生じたとしても前記変調レーザ光成分自体を一定に保つことができる。従って、例えば前記変調レーザ光成分を分析して求められる計測対象物までの距離を正確に得ることが可能となる。即ち、本発明に係るレーザ装置によればレーザ素子の温度ドリフト等の影響を受けることなく、計測対象物までの高精度な距離計測を行ったり、計測対象物の振動・変位検出等を高精度に行うことが可能となる。しかも簡易な制御だけで、その計測精度を保証することが可能となる。   In the laser apparatus having the above-described configuration, information on the modulated laser light component generated by the self-coupling effect of the laser element due to the reflected light from a preset reference point, specifically, the interference component between the output light and the reflected light Since the drive condition of the laser element is feedback controlled so as to keep the beat number and frequency constant, the modulated laser light component itself can be kept constant even if a temperature drift occurs in the laser element. Therefore, for example, it is possible to accurately obtain the distance to the measurement object obtained by analyzing the modulated laser beam component. That is, according to the laser device of the present invention, it is possible to measure the distance to the measurement object with high accuracy and to detect the vibration / displacement of the measurement object without being affected by the temperature drift of the laser element. Can be performed. In addition, the measurement accuracy can be guaranteed only with simple control.

以下、図面を参照して本発明の一実施形態に係るレーザ装置について説明する。
図3はこの実施形態に係るレーザ装置の要部概略構成図である。このレーザ装置は基本的には図1に示すレーザ装置と同様に構成され、特にレーザ素子1は受光器3と共に密閉ケース8に収納されてモジュール化(パッケージ化)されている。そしてレーザ素子1から出力されたレーザ光は、該レーザ素子1の前面に対峙させて前記密閉ケース8に設けられたガラス等の透明カバー7を通して計測対象物2に照射され、また計測対象物2による反射光は上記透明カバー7を通してレーザ素子1に戻るようになっている。
A laser apparatus according to an embodiment of the present invention will be described below with reference to the drawings.
FIG. 3 is a schematic configuration diagram of a main part of the laser apparatus according to this embodiment. This laser device is basically configured in the same manner as the laser device shown in FIG. 1, and in particular, the laser element 1 is housed in a sealed case 8 together with the light receiver 3 and is modularized (packaged). The laser light output from the laser element 1 is irradiated onto the measurement object 2 through the transparent cover 7 such as glass provided on the sealed case 8 so as to face the front surface of the laser element 1, and the measurement object 2. The reflected light from the light returns to the laser element 1 through the transparent cover 7.

また前記受光器3の出力から前記レーザ素子1の自己結合効果により生じた干渉成分を検出する周波数分析部5は、レーザ素子1から出力されるレーザ光(出力光)と前記計測対象物2からの反射光との干渉成分のみならず、上記レーザ光(出力光)と前記透明カバー7にて反射したレーザ光(戻り光)との干渉成分をも検出している。特に周波数分析部5は、上記透明カバー7での反射光と出力光との干渉成分の情報を波長変調部4にフィードバックすることで、後述するように前記レーザ素子1の変調条件を制御するように構成されている。尚、図中6は周波数分析されたレーザ光の干渉成分から、前記計測対象物2までの距離を求める距離検出部である。   The frequency analysis unit 5 that detects an interference component generated by the self-coupling effect of the laser element 1 from the output of the light receiver 3 receives the laser beam (output light) output from the laser element 1 and the measurement object 2. In addition to the interference component with the reflected light, the interference component between the laser beam (output beam) and the laser beam (return beam) reflected by the transparent cover 7 is also detected. In particular, the frequency analysis unit 5 feeds back information on interference components between the reflected light and output light from the transparent cover 7 to the wavelength modulation unit 4 so as to control the modulation conditions of the laser element 1 as will be described later. It is configured. In the figure, reference numeral 6 denotes a distance detection unit that obtains the distance to the measurement object 2 from the interference component of the laser beam subjected to frequency analysis.

具体的には図4にその要部概略構成を示すように、受光器3と共に密閉ケース8に収納されてモジュール化された前記レーザ素子1の前面には、その窓部を形成して前記レーザ素子1を保護する透明カバー(透明体)7が設けられている。特に上記透明カバー7のレーザ素子1側に位置付けられる内側面には反射防止膜9が設けられて前記レーザ素子1から射出されるレーザ光の反射が防止されており、また前記透明カバー7の計測対象物2側に位置付けられる外側面(レーザ測長器の外部露出面)は、若干の反射が生じるように設定されている。透明カバー7の若干の反射が生じるように処理を施した上記外側面(レーザ測長器の外部露出面)は、後述するようにレーザ測長器における計測基準点として用いられる。   Specifically, as shown in FIG. 4, a schematic configuration of a main part thereof, the window portion is formed on the front surface of the laser element 1 which is housed in a sealed case 8 together with the light receiver 3 and modularized, and the laser A transparent cover (transparent body) 7 for protecting the element 1 is provided. In particular, an antireflection film 9 is provided on the inner side surface of the transparent cover 7 positioned on the laser element 1 side to prevent reflection of laser light emitted from the laser element 1, and measurement of the transparent cover 7 is performed. The outer surface (externally exposed surface of the laser length measuring device) positioned on the object 2 side is set so that slight reflection occurs. The outer side surface (externally exposed surface of the laser length measuring device) that has been processed so that slight reflection of the transparent cover 7 occurs is used as a measurement reference point in the laser length measuring device, as will be described later.

即ち、ガラス等の透明体(透明カバー7)を通してレーザ光を入出力する場合、透明体と空気との界面で僅かではあるがレーザ光の反射が生じる。このような反射を防ぐ場合、専ら、低屈折率材料を分散させたフィラーを上記透明体の表面にコーティングして反射防止膜を形成することが行われる。本発明に係るレーザ測長器においても、レーザ光の入出射面となる透明カバー7での不要な反射を抑えるべく、上記透明カバー7の表面に反射防止膜(ARコート)9を設けるが、この際、透明カバー7の内側面にだけ反射防止膜9を設け、敢えて透明カバー7の外側面においてレーザ光の反射が生じるようにしている。そしてレーザ素子1から出力されたレーザ光の一部が上記透明カバー7の外側面にて反射して前記レーザ素子1に戻るようにしている。   That is, when laser light is input / output through a transparent body (transparent cover 7) such as glass, the laser light is slightly reflected at the interface between the transparent body and air. In order to prevent such reflection, an antireflection film is formed exclusively by coating the surface of the transparent body with a filler in which a low refractive index material is dispersed. Also in the laser length measuring device according to the present invention, an antireflection film (AR coating) 9 is provided on the surface of the transparent cover 7 in order to suppress unnecessary reflection on the transparent cover 7 which is the laser light incident / exit surface. At this time, the antireflection film 9 is provided only on the inner surface of the transparent cover 7 so that the laser beam is reflected on the outer surface of the transparent cover 7. A part of the laser beam output from the laser element 1 is reflected by the outer surface of the transparent cover 7 and returns to the laser element 1.

尚、前記透明カバー7の外側面については、無反射防止処理を施さないことは勿論のことではあるが、敢えて前記レーザ素子において自己結合効果が生じる強度の反射光を得るに必要な処理を施すようにしても良い。具体的には前記透明カバー4の外側面を鏡面研磨したり、或る程度の反射率を有する光学膜を被覆形成することも可能である。しかしレーザ装置の主たる役割は、計測対象物2にレーザ光を照射し、その反射光をレーザ素子1に戻して計測対象物2までの距離等を計測することにあるので、前述した透明カバー7における反射をできるだけ抑えることが望ましい。   The outer surface of the transparent cover 7 is of course not subjected to antireflection processing, but is intentionally subjected to processing necessary to obtain reflected light having an intensity that causes a self-coupling effect in the laser element. You may do it. Specifically, the outer surface of the transparent cover 4 can be mirror-polished, or an optical film having a certain reflectivity can be formed by coating. However, the main role of the laser device is to irradiate the measurement object 2 with laser light and return the reflected light to the laser element 1 to measure the distance to the measurement object 2. It is desirable to suppress reflections at as much as possible.

このように構成されたレーザ装置によれば、レーザ素子1から出力され、透明カバー7を介して計測対象物2に向けて照射されたレーザ光が該計測対象物2により反射され、上記透明カバー7を通してレーザ素子1に戻ると共に、前記透明カバー7の外側面にて反射されたレーザ光も前記レーザ素子1に戻ることになる。この結果、レーザ素子1においては、その出力光と計測対象物2における反射光との自己結合効果による干渉が生じると共に、上記出力光と透明カバー7における反射光との自己結合効果による干渉が生じる。   According to the laser device configured as described above, the laser light output from the laser element 1 and irradiated toward the measurement object 2 via the transparent cover 7 is reflected by the measurement object 2, and the transparent cover The laser beam reflected by the outer surface of the transparent cover 7 is also returned to the laser element 1. As a result, in the laser element 1, interference due to the self-coupling effect between the output light and the reflected light from the measurement object 2 occurs, and interference due to the self-coupling effect between the output light and the reflected light from the transparent cover 7 occurs. .

すると上記計測対象物2および透明カバー7にてそれぞれ生じた反射光(戻り光)に対応して前記レーザ光の干渉成分が、例えば図5に示すように互いに異なる周波数成分fo,f1として生じる。そしてこれらの干渉成分の周波数fo,f1は、レーザ素子1から透明カバー7までの距離Lo、および計測対象物2までの距離Lにそれぞれ対応することになる。従って上記レーザ素子1の自己結合効果により生じた干渉成分の周波数fo,f1をそれぞれ検出し、これらの各周波数周波数fo,f1に相当する距離情報Lo,Lを求めれば、前述した透明カバー7を計測基準点として該計測基準点(透明カバー7)から計測対象物2までの距離Lsを[=L−Lo]として高精度に計測することが可能となる。   Then, the interference components of the laser beam corresponding to the reflected light (return light) respectively generated by the measurement object 2 and the transparent cover 7 are generated as frequency components fo and f1 which are different from each other as shown in FIG. The frequencies fo and f1 of these interference components correspond to the distance Lo from the laser element 1 to the transparent cover 7 and the distance L from the measurement object 2, respectively. Accordingly, if the interference components frequencies fo and f1 generated by the self-coupling effect of the laser element 1 are detected and distance information Lo and L corresponding to these frequency frequencies fo and f1 are obtained, the above-described transparent cover 7 is obtained. As a measurement reference point, the distance Ls from the measurement reference point (transparent cover 7) to the measurement object 2 can be measured with high accuracy as [= L−Lo].

またこのようにして透明カバー7の外側面においてレーザ光の反射が生じるようにしておけば、レーザ測長器におけるレーザ素子1と透明カバー7との位置関係に個体差(バラツキ)が存在しても、上記透明カバー7の外側面を計測基準点として計測対象物2までの距離Lを高精度に測定することができるので、例えば量産されるレーザ測長器の個体差に拘わりなく信頼性の高い距離計測を行うことが可能となる。特にこの種のレーザ測長器を工場等の現場に設置して用いる場合、専ら、予め設定された計測原点からの計測対象物2の距離(位置)が計測対象となることが多い。この場合、レーザ測長器のレーザ光入出射端面となる前述した透明カバー7の外側面を上記計測原点に突き合わせして該レーザ測長器の取り付け位置を決定(調整)するだけで良いので、その取り扱いの容易化を図ることが可能となる。 In addition, if laser light is reflected on the outer surface of the transparent cover 7 in this way, there is an individual difference (variation) in the positional relationship between the laser element 1 and the transparent cover 7 in the laser length measuring device. In addition, since the distance L S to the measurement object 2 can be measured with high accuracy using the outer surface of the transparent cover 7 as a measurement reference point, reliability can be achieved regardless of individual differences in mass-produced laser length measuring instruments. It is possible to perform a high distance measurement. In particular, when this type of laser length measuring device is installed and used at a site such as a factory, the distance (position) of the measurement object 2 from the preset measurement origin is often the measurement object. In this case, it is only necessary to determine (adjust) the mounting position of the laser length measuring device by abutting the outer surface of the transparent cover 7 described above serving as the laser light incident / exit end surface of the laser length measuring device with the measurement origin. The handling can be facilitated.

ところで前述したようにレーザ素子1からの出力光の強度(光量)Pおよび発振波長λは、レーザ素子1の温度Tによっても変化する。するとレーザ素子1から出力されるレーザ光の波長変調帯域が変化し、これに伴ってレーザ素子1における自己結合作用によって生じる干渉成分の周波数も変化する。この結果、上記レーザ光の干渉成分を分析して検出される計測対象物2までの距離にずれが生じると言う問題が生じる。   Incidentally, as described above, the intensity (light quantity) P of the output light from the laser element 1 and the oscillation wavelength λ also change depending on the temperature T of the laser element 1. Then, the wavelength modulation band of the laser light output from the laser element 1 changes, and accordingly, the frequency of the interference component generated by the self-coupling action in the laser element 1 also changes. As a result, there arises a problem that the distance to the measurement object 2 detected by analyzing the interference component of the laser beam is shifted.

そこで本発明に係るレーザ測長器においては、レーザ素子1が出力するレーザ光と前述した計測基準点として用いる透明カバー7の外側面からの反射光との自己結合効果による干渉成分に着目し、上記計測基準点からの反射光による干渉成分に基づいて前記レーザ素子1の駆動条件をフィードバック制御している。具体的にはレーザ素子1の駆動電流そのものや、レーザ光を波長変調するべく周期的に増減される駆動電流の振幅または周期をフィードバック制御することで、上記干渉成分のビート数や周波数等の情報を一定に保つようにしている。   Therefore, in the laser length measuring device according to the present invention, paying attention to the interference component due to the self-coupling effect between the laser light output from the laser element 1 and the reflected light from the outer surface of the transparent cover 7 used as the measurement reference point described above, The drive condition of the laser element 1 is feedback-controlled based on the interference component due to the reflected light from the measurement reference point. Specifically, information such as the beat number and frequency of the interference component is controlled by feedback control of the drive current itself of the laser element 1 and the amplitude or period of the drive current that is periodically increased or decreased to modulate the wavelength of the laser beam. Is kept constant.

即ち、半導体レーザ素子1の自己結合効果を利用して計測対象物までの距離L等を計測するレーザ装置においては、その駆動電流に応じてレーザ素子1の発振波長λが該レーザ素子1の波長変化率特性の変化に伴って変化すると、自己結合効果により生じる干渉信号も変化する。具体的には、例えば図6(a)に示すよう周期的な三角波からなる駆動電流をレーザ素子10に加えてレーザ発振させ、その出力光と反射光との自己結合効果により生じた干渉信号が重畳したレーザ光を受光器13にて受光した場合、受光器13での受光量(起電流)は図6(b)に示すようになる。しかしレーザ素子1の波長変化率特性が温度変化等に起因して図6(c)に示すように変化すると、発振波長の変化に伴って干渉条件が変化するので、上記受光器13での受光量(起電流)は図6(d)に示すように変化する。即ち、発振波長のずれに伴って周波数f(0)で生じていた干渉が、周波数f(1)で生じるようになる。この干渉成分の波長のずれが、計測誤差の要因となる。   That is, in a laser apparatus that measures the distance L to the measurement object using the self-coupling effect of the semiconductor laser element 1, the oscillation wavelength λ of the laser element 1 is the wavelength of the laser element 1 according to the drive current. When the change rate changes with the change rate characteristic, the interference signal generated by the self-coupling effect also changes. Specifically, for example, as shown in FIG. 6A, a drive current composed of a periodic triangular wave is applied to the laser element 10 to cause laser oscillation, and an interference signal generated by the self-coupling effect between the output light and the reflected light is generated. When the superimposed laser beam is received by the light receiver 13, the amount of light received (electromotive current) by the light receiver 13 is as shown in FIG. However, if the wavelength change rate characteristic of the laser element 1 changes as shown in FIG. 6C due to a temperature change or the like, the interference condition changes along with the change of the oscillation wavelength. The quantity (electromotive current) changes as shown in FIG. That is, the interference that occurred at the frequency f (0) due to the oscillation wavelength shift occurs at the frequency f (1). This shift in the wavelength of the interference component causes a measurement error.

そこで本発明に係るレーザ測長器においては、前述したようにしてレーザ素子10の発振波長の変化幅の範囲において上述した干渉成分の周波数を検出している。そして、例えば干渉周波数のずれを[K・f(1)→f(0)]として補正する補正係数Kを計算し、この補正係数Kに基づいてレーザ素子10の駆動電流を補正してその発振波長λ自体を補正するようにしている。   Therefore, in the laser length measuring device according to the present invention, the frequency of the interference component described above is detected within the range of change in the oscillation wavelength of the laser element 10 as described above. Then, for example, the correction coefficient K for correcting the deviation of the interference frequency as [K · f (1) → f (0)] is calculated, the drive current of the laser element 10 is corrected based on the correction coefficient K, and the oscillation is performed. The wavelength λ itself is corrected.

尚、検出した干渉成分の周波数に基づいて、例えば図5(e)に示すようにレーザ素子10に加える駆動電流(三角波)の周期を調整し、これによって図5(f)に示すように周波数f(0)にて干渉が生じるようにしたり、更には図5(g)に示すようにレーザ素子10に加える駆動電流(三角波)の振幅を調整し、これによって図5(h)に示すように周波数f(0)にて干渉が生じるようにしても良い。即ち、レーザ素子1の自己結合効果を利用した計測系においては、自己結合効果により生じた干渉信号の周波数成分がレーザ光の反射点までの距離情報を示すことになるので、レーザ素子10の発振波長自体を補正するべく補正係数に従ってその駆動電流を補正したり、連続的に増減される上記駆動電流の周期および/または振幅を調整してその共振条件を補正するようにすれば良い。   Based on the detected frequency of the interference component, for example, as shown in FIG. 5 (e), the period of the drive current (triangular wave) applied to the laser element 10 is adjusted, so that the frequency as shown in FIG. 5 (f) is obtained. As shown in FIG. 5 (h), interference occurs at f (0), or the amplitude of the drive current (triangular wave) applied to the laser element 10 is adjusted as shown in FIG. 5 (g). In addition, interference may occur at the frequency f (0). That is, in the measurement system using the self-coupling effect of the laser element 1, the frequency component of the interference signal generated by the self-coupling effect indicates the distance information to the reflection point of the laser beam. In order to correct the wavelength itself, the drive current may be corrected according to a correction coefficient, or the resonance condition may be corrected by adjusting the period and / or amplitude of the drive current that is continuously increased or decreased.

かくして上述したように本発明に係るレーザ装置においては、計測基準点からの反射光によって生じた干渉成分の周波数を一定に保つようにレーザ素子1の駆動条件をフィードバック制御するので、仮に温度変化に起因してレーザ素子1の波長変化率特性が変化しても、レーザ素子1の自己結合効果による干渉成分に基づく計測対象物2までの距離測定等の計測条件を一定に保つことができる。この結果、その計測信頼性を高めて常に高精度な距離計測等を行うことが可能となる。   Thus, as described above, in the laser apparatus according to the present invention, the drive condition of the laser element 1 is feedback controlled so as to keep the frequency of the interference component generated by the reflected light from the measurement reference point constant. Therefore, even if the wavelength change rate characteristic of the laser element 1 changes, measurement conditions such as distance measurement to the measurement object 2 based on the interference component due to the self-coupling effect of the laser element 1 can be kept constant. As a result, it is possible to improve the measurement reliability and always perform highly accurate distance measurement.

しかも上述したように理論的に計算される補正係数に基づいてレーザ素子1の駆動電流を補正したり、或いはレーザ光を波長変調するべく周期的に増減される駆動電流の振幅またはその周期をフィードバック制御するだけで良いので、簡単な制御系の下で距離計測の信頼性とその計測精度とを十分に高めることが可能となる。従ってその実用的利点が多大である。   In addition, as described above, the drive current of the laser device 1 is corrected based on the correction coefficient calculated theoretically, or the amplitude of the drive current that is periodically increased or decreased to modulate the wavelength of the laser beam or its period is fed back. Since only the control is required, the reliability of the distance measurement and the measurement accuracy can be sufficiently increased under a simple control system. Therefore, its practical advantage is great.

尚、上述した実施形態においては、レーザ測長器における密閉ケース8の窓部に嵌め込まれる透明カバー7の外側面を計測基準点として用いたが、例えばレーザ素子1だけをキャン・パッケージに封入してレーザ素子を単体で用いるような場合、上記キャン・パッケージの窓部に設けられる透明カバー7を測定基準点として用いても良いことは言うまでもない。またレーザ素子1に対峙させて光ファイバを設け、この光ファイバを通してその先端部から計測対象物2に向けてレーザ光を入出力する場合には、上記光ファイバの計測対象物2に対峙させて設けられるレーザ光の入出射面(ファイバ端面)を計測基準点として用いることも可能である。   In the above-described embodiment, the outer surface of the transparent cover 7 fitted into the window of the sealed case 8 in the laser length measuring device is used as a measurement reference point. For example, only the laser element 1 is enclosed in a can package. When the laser element is used alone, it goes without saying that the transparent cover 7 provided in the window portion of the can package may be used as a measurement reference point. Further, when an optical fiber is provided facing the laser element 1 and laser light is input / output from the distal end portion toward the measurement object 2 through the optical fiber, the optical fiber is opposed to the measurement object 2 of the optical fiber. It is also possible to use a laser light incident / exit surface (fiber end surface) provided as a measurement reference point.

更には計測対象物2が所定の空間(計測対象領域)に設けられるような場合であって、その計測対象領域に計測対象物2が存在しない場合には、レーザ素子1から出力されたレーザ光は上記計測対象物の背景面(バックグラウンド)にて反射することになる。そしてこの計測対象物の背景面(バックグラウンド)は、通常、固定的(不変的)に設定されることが多い。従って図4に併せて示すように、計測対象領域の背景面(バックグラウンド)11を基準点として用い、上記背景面11からの反射光による干渉成分を検出して前記レーザ素子1の駆動電流をフィードバック制御することも勿論可能である。要は本発明は、その要旨を逸脱しない範囲で種々変形して実施することができる。   Further, in the case where the measurement object 2 is provided in a predetermined space (measurement object area) and the measurement object 2 does not exist in the measurement object area, the laser beam output from the laser element 1 Is reflected on the background surface of the measurement object. The background surface (background) of the measurement object is usually set to be fixed (invariant) in many cases. Therefore, as shown in FIG. 4, the background surface (background) 11 of the measurement target region is used as a reference point, the interference component due to the reflected light from the background surface 11 is detected, and the drive current of the laser element 1 is calculated. Of course, feedback control is also possible. In short, the present invention can be implemented with various modifications without departing from the spirit of the present invention.

レーザ素子の自己結合効果を利用したレーザ装置の基本的な構成を示す図。The figure which shows the basic composition of the laser apparatus using the self-coupling effect of a laser element. レーザ素子から出力される波長変調したレーザ光の強度と、その干渉成分の例を示す図。The figure which shows the example of the intensity | strength of the wavelength-modulated laser beam output from a laser element, and its interference component. 本発明の一実施形態に係るレーザ装置の概略構成を示す図。The figure which shows schematic structure of the laser apparatus which concerns on one Embodiment of this invention. レーザ素子から出力されたレーザ光の透明カバーおよび計測対象領域の背景面(バックグラウンド)での反射の様子を模式的に示す図。The figure which shows typically the mode of reflection in the background surface (background) of the transparent cover and measurement object area | region of the laser beam output from the laser element. 複数の反射点からの戻り光により生じる干渉成分の周波数の違いを示す図。The figure which shows the difference in the frequency of the interference component produced by the return light from a several reflective point. 本発明に係るレーザ装置における基準点からの反射光による干渉成分の周波数の変化と、レーザ素子の駆動条件のフィードバック制御による補正の形態を示す図。The figure which shows the form of correction | amendment by feedback control of the change of the frequency of the interference component by the reflected light from the reference point in the laser apparatus which concerns on this invention, and the drive condition of a laser element.

符号の説明Explanation of symbols

1 レーザ素子
2 計測対象物
3 受光器
7 透明カバー(透明体)
10 光ファイバ
11 計測対象領域の背景面
DESCRIPTION OF SYMBOLS 1 Laser element 2 Measurement object 3 Light receiver 7 Transparent cover (transparent body)
10 Optical fiber 11 Background of measurement target area

Claims (4)

計測対象物に向けて波長変調したレーザ光を照射すると共に、上記計測対象物にて反射した上記レーザ光が導入される自己結合型のレーザ素子を備え、このレーザ素子におけるレーザ光の自己結合効果により生じた変調レーザ光を分析して前記計測対象物の状態を検出するレーザ装置であって、
予め設定された基準点からの反射光により前記レーザ素子の自己結合効果により生じた変調レーザ光成分の情報に基づいて、該変調レーザ光成分を一定に保つように前記レーザ素子の駆動条件をフィードバック制御することを特徴とするレーザ装置。
A self-coupled laser element that irradiates the measurement target with wavelength-modulated laser light and introduces the laser light reflected by the measurement target is provided. The self-coupling effect of the laser light in this laser element A laser device that detects the state of the measurement object by analyzing the modulated laser beam generated by
Based on the information of the modulated laser light component generated by the self-coupling effect of the laser element by the reflected light from the preset reference point, the driving condition of the laser element is fed back so as to keep the modulated laser light component constant. A laser device characterized by controlling.
前記予め設定された基準点は、計測対象領域に検出対象物が存在しない場合における上記計測対象領域の背景面、またはレーザ素子からの出力されたレーザ光の前記計測対象領域に対する入出射面である請求項1に記載のレーザ装置。   The preset reference point is a background surface of the measurement target region when a detection target does not exist in the measurement target region, or an entrance / exit surface of the laser light output from the laser element with respect to the measurement target region. The laser device according to claim 1. 前記レーザ素子の駆動条件のフィードバック制御は、前記変調レーザ光成分の周波数が予め設定した周波数となる補正係数を求め、この補正係数に従って前記レーザ素子の駆動条件を補正して行われるものである請求項1に記載のレーザ装置。   The feedback control of the driving condition of the laser element is performed by obtaining a correction coefficient at which the frequency of the modulated laser light component becomes a preset frequency and correcting the driving condition of the laser element according to the correction coefficient. Item 2. The laser device according to Item 1. 前記レーザ光の波長変調は、前記レーザ素子の駆動電流を周期的に増減させて行われるものであって、前記レーザ素子の駆動条件のフィードバック制御は、上記駆動電流の振幅または前記駆動電流の増減周期を変化させて行われるものである請求項1に記載のレーザ装置。   The wavelength modulation of the laser beam is performed by periodically increasing / decreasing the driving current of the laser element, and feedback control of the driving condition of the laser element is performed by changing the amplitude of the driving current or the increasing / decreasing of the driving current. The laser apparatus according to claim 1, wherein the laser apparatus is performed while changing a cycle.
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JP2011520280A (en) * 2008-05-09 2011-07-14 コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ Vertical cavity surface emitting laser
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JP2018013370A (en) * 2016-07-20 2018-01-25 株式会社デンソーウェーブ Laser radar device
JP2019078679A (en) * 2017-10-26 2019-05-23 サカエ理研工業株式会社 Door handle device for vehicle, and vehicle
WO2021086031A1 (en) * 2019-10-31 2021-05-06 부산대학교 산학협력단 Dual variable-based oscillation optical frequency scanning laser light source, measurement device using same, and distance measurement device according to object angle, which uses propagation angle switching for each center wavelength
KR102353365B1 (en) * 2020-08-31 2022-01-19 부산대학교 산학협력단 Device for Measuring Distance According to the Angle of the Object using the Conversion of the Propagation Angle for Each Center Wavelength of the Color Shift Laser

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