DE4215984C1 - Optical ranging device, e.g. FM laser radar - has laser and associated Faraday rotator sandwiched between two analysers with maximum transparency for 45 degree rotated radiation - Google Patents

Abstract

The optical ranging device has a detector (1), an analyser (2), a laser (3), a Faraday rotator (4) and a second analyser positioned in series one behind the other. The output of the laser (3) is directed both ways and received by the analyser (2) and the Faraday rotator (4), providing a rotation in the polarisation direction of 45 degrees. The second analyser (5) receives this radiation and the radiation reflected from the object (6) at the unknown distance and exhibits a max. transparency for the radiation from the Faraday rotator (4), the first analyser having a max transparency for the laser radiation rotated through 45 degrees. Pref a frequency modulated laser (3) is used. ADVANTAGE - Measuring frequency of up to 1000000 measurements per sec. can be used.

Description

The present invention relates to an arrangement for optical distance measurement with high measuring frequency.

When measuring distances in the micrometer range with a high measuring frequency (up to over 10 ⁶ measurements per second), the arrangement shown in the diagram in FIG. 4 is usually used. A laser beam from the laser L is directed onto the object O and the reflected beam is brought into interference with the laser beam. The interfering rays are collected in a detector and mixed. Since the laser frequency changes over time (e.g. sawtooth-shaped), the two beams (the emitted and the reflected) have a different frequency due to the time shift proportional to the path length difference, which can be electronically removed as a mixed product at the detector. In addition to the laser L and the detector D, an isolator I and a beam splitter S are also shown in FIG. 4 as components of the apparatus. The isolator I prevents the reflected beam from entering the laser L. The beam splitter S ensures the reflection of the two partial beams to be mixed with one another. It essentially consists of a semi-transparent mirror arranged at an angle of 45 °. A mirror M ensures the reflection of the partial beam striking the object O. The beam running from the laser to the object is shown with solid arrows, the reflected beam with broken arrows. A major disadvantage of this arrangement is the complex beam splitting and adjustment as well as the corresponding power losses.

Such an arrangement is e.g. B. in the publication by A. R. Slotwinski: "Utilizing GaAlAs Laser Diodes as a Source for Frequency Modulated Continuous Wave (FMCW) Cohe Rent Laser Radars "in SPIE 1043, 245 to 251 (1989) ben.

In US 33 26 078 an arrangement for measuring Rela tiv movement between objects specified in the case of two lasers same wavelength can be used. By an order with a semi-transparent mirror it is achieved that the path lengths from the laser to the object and back between them Distinguish lasers by a quarter laser wavelength. The Lasers are provided with Brewster windows. Between the La and the semi-transparent mirror that reflects the beam paths are for a polarization of light for each laser has separate polarizers. On the opposite Photodetectors are arranged on the side of the lasers net.

In US 45 30 600 a range finder is described where a laser, a rotating polarizer, one as a beam splitter functioning polarizer, a collimator and the one to be measured Object are arranged in a row one behind the other. The one from that The light beam reflected by the object is Beam splitter reflected to a photo detector.

The object of the present invention is an arrangement to specify high-resolution optical distance measurement, where no complex beam splitting is required.

This task is accomplished with the arrangement with the characteristics of Claim 1 solved. Another configuration results itself from the dependent claims.

The arrangement according to the invention is shown in the diagram in FIG. 1. Fig. 2 and 3 contain plots to the polarization direction of the radiation.

In the arrangement according to the invention, a detector 1 , a first analyzer 2 (polarizer), a laser 3 , a Faraday rotator 4 and a second analyzer 5 (polarizer) are arranged in series. The laser 3 emitting in the longitudinal direction on the end faces is so directed that the radiation emerging on both sides is directed onto the first analyzer 2 or the Faraday rotator 4 . The Faraday rotator 4 rotates the polarization direction of the laser light by 45 °, specifically in the same direction, that is to say independently of the direction in which the radiation passes through this rotator. The laser beam passes after the Faraday rotator 4, the second analyzer 5 , which is designed so that it is maximally transparent to the radiation emerging from the Faraday rotator 4 . The radiation emerging from the second analyzer 5 is directed onto the object 6 , the distance of which is to be measured, and is reflected back by the latter into this second analyzer 5 . Only that portion of the reflected radiation passes through the second analyzer 5 and again into the Faraday rotator 4 that has the polarization direction corresponding to the orientation of the second analyzer 5 . The Faraday rotator 4 rotates this direction again by 45 °, in the same direction as before, ie opposite to the direction of radiation. This results in a total rotation of the polarization direction of 90 ° with respect to the polarization direction of the light originally emitted by the laser for the radiation emerging from the Faraday rotator 4 . This reflected by 90 ° re reflected radiation enters the laser 3 and is amplified there if necessary. At the other end of the laser, the reflected radiation, together with the light emitted by the laser at this end, enters and enters the first analyzer 2 . This first analyzer 2 is rotated by 45 ° with respect to the plane of polarization of the light emitted by the laser. This first analyzer 2 is therefore maximally transparent to light with a polarization direction rotated by 45 ° compared to the laser light. It is then also rotated by 45 ° compared to the reflected light, so that only a portion of each beam is passed. These parts are collected and processed by the detector 1 .

Figs. 2 and 3 illustrate the polarization direction of the radiation in different portions of the assembly. In Fig. 2 the vertical solid arrow is the polarization direction of the radiation emerging from the laser 3 in the direction of the Faraday rotator 4 . The Faraday rotator 4 rotates the direction of polarization accordingly the dash-dotted arrow to the second solid arrow pointing from bottom left to top right. The proportion of the reflected beam that is transmitted through the second analyzer 5 has a correspondingly lower amplitude, which corresponds to the length of the dashed arrow. As in Fig. 1, the dashed arrow ge is drawn for the reflected beam. When the radiation passes through the Faraday rotator 4 again, the polarization direction is rotated for the second time by 45 ° in the direction of the dash-dotted arrow, so that the polarization direction and amplitude is given by the horizontal arrow in FIG. 2. The radiation then enters laser 3 again , in which it is optionally amplified. In order to indicate this reinforcement, the horizontal dashed arrow in Fig. 3 is shown somewhat longer than in Fig. 2 (larger amplitude). The direction of polarization and amplitude of the laser radiation emerging from the laser 3 in the direction of the first analyzer 2 is shown in FIG. 3 by the solid vertical arrow. The alignment of the first analyzer 2 is assumed in FIG. 3 as the bisector between the arrows. In contrast, the orientation can also be rotated by 90 °, which serves the same purpose in the arrangement according to the invention. The orientation of this first analyzer 2 be that only the projections of the light amplitudes indicated by the dash-dotted lines on the bisector of the angle are passed through the analyzer. The polarization directions for both parts of the beam are then the same, the lengths of the amplitudes are each reduced by a factor of ^2½ , which corresponds to the shorter arrows drawn along the bisector of the angle.

Two basic principles of the present invention are that the radiation emerging from the laser on both sides is used becomes, which increases the sensitivity of the arrangement and that the arrangement is linear, which means that he it is enough that the reflected beam fully fills the laser constantly happening. The use of the Faraday rotator be intends that the polarization directions of the emitted Laser radiation and the reflected radiation orthogonal to each other so that there is an interaction of these Radiation components in the laser is avoided. The reflected  If necessary, the beam can be amplified in the laser that the reduction in the output of both beams by 50% at least when passing through the first analyzer can be partially compensated.

The present invention represents a simple concept for an FM laser radar. As a frequency-modulated laser, the TTG semiconductor laser (tunable twin guide) is particularly suitable for this arrangement. In addition to the simpler structure, the arrangement according to the invention has the advantage that the (otherwise unused) rear laser beam is used for detection. Therefore, the sensitivity is increased compared to conventional arrangements (see. Fig. 4).

Claims (3)

1. arrangement for optical distance measurement,
in which a detector ( 1 ), a first analyzer ( 2 ), a laser ( 3 ) with radiation exit on both sides, a Faraday rotator ( 4 ), a second analyzer ( 5 ) and an object ( 6 ) along a radiation path whose distance is to be measured are arranged in this order
in which the laser ( 3 ) is oriented such that radiation emerging from the laser ( 3 ) on both sides is directed onto the Faraday rotator ( 4 ) or the first analyzer ( 2 ),
in which the Faraday rotator ( 4 ) causes a rotation of the polarization direction of radiation by 45 °, in which the second analyzer ( 5 ) is oriented such that it is emitted by the laser ( 3 ) and through the Faraday Rotator ( 4 ) de radiation is maximally transmissive and the object ( 6 ) reflects radiation back into it, and
in which the first analyzer ( 2 ) is oriented such that it is maximally transparent to radiation with a polarization direction rotated by 45 ° with respect to the radiation emitted by the laser ( 3 ). 2. Arrangement according to claim 1, wherein the laser ( 3 ) is a frequency-modulated laser. 3. Arrangement according to claim 1 or 2, wherein the laser ( 3 ) radiation with a direction of polarization, which is rotated by 90 ° with respect to the polarization direction of the laser radiation generated by the laser ( 3 ), ver.