Optics: measuring and testing – By light interference – Having light beams of different frequencies
Reexamination Certificate
1999-09-03
2001-02-13
Kim, Robert (Department: 2877)
Optics: measuring and testing
By light interference
Having light beams of different frequencies
C356S489000, C356S485000
Reexamination Certificate
active
06188480
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to a method of interferometric measurement of positions and position changes, as well as of physical quantities derived therefrom, of a part to be tested, using heterodyne interferometry, with a laser being modulated to change the frequency of the radiation emitted by it using a time-variable pulsating injection current, in order to generate the heterodyne frequency, and portion of the emitted radiation is routed via an optical bypass, while the other portion is routed without the optical bypass to the part and therefrom to a measuring receiver.
BACKGROUND INFORMATION
Such a method is known in conjunction with different optical systems and is described, for example, in European Patent No. 420 897 B1. In order to generate the heterodyne frequency, which is well-suited for the quantitative evaluation, the radiation emitted by the semiconductor laser (laser diode) is modulated using a time-variable injection current. The radiation emitted by the laser is divided into two beams, one of which is routed via an optical bypass and the other is routed without an optical bypass to the part to be tested. The optical bypass is implemented, for example, using deflecting mirrors or a light guide loop. Details of heterodyne interferometric measurement can be found in the aforementioned document.
Other embodiments for heterodyne interferometric measurement of positions, position changes, rotation angles, speeds and other physical quantities derived therefrom are known, with the optical bypass being implementable using a bypass prism. With these methods and measuring devices, positions or path differences, as well as quantities derived therefrom, can be measured with high accuracy, for example, in the nm range. To modulate the laser, the signal of the injection current in these known methods and devices has a sinusoidal, triangular or sawtooth shape with a rising edge that is flat compared with the pulse period, since only such signal shapes are considered suitable for obtaining reliable measurement results. In these methods, the typical length of the optical bypass, for example, for a heterodyne frequency in the MHZ range as customarily used, is on the order of a few decimeters, for example, 40 cm. This relatively long optical bypass runs counter to the desired miniaturization of measurement systems. In addition, by increasing the length of the optical bypass, the contrast of the interference pattern to be evaluated, which is required for the evaluation and should be as high as possible, is diminished, as can be seen from the coherence function, which shows the drop in contrast with increasing length of the optical bypass AL in the form of an exponential function. In this case, evaluation is made difficult by back reflexes of the optical system onto the laser diode, which results in the otherwise single-mode operation of the laser becoming multimode with a peak-shaped coherence function being obtained and the exponential function being the envelope and dropping more steeply than in single-mode operation. In order to avoid back reflexes, an isolator, for example, must be located upstream from the laser, which results in further expenses.
In another measurement method, i.e, a spectroscopic measurement of exhaled air, it is known from Lachish et al., “Tunable diode laser based spectroscopic system for ammonia detection in human respiration,” the Review of Scientific Instrument, Vol. 58, No. 6, June 1987, pp. 923-927, that a semiconductor laser can be controlled using a rectangular modulation current to detect a null signal during consecutive light pulses. The semiconductor laser is temperature stabilized in this method.
U.S. Pat. No. 4,765,738 proposes that, in order to measure the frequency response of an optical receiver system, a heterodyne frequency be generated using a laser diode and an optical bypass, with a rectangular modulation being performed, among other things, in order to control a semiconductor laser. Frequencies up to 10 GHz are to be measured with this method. An optical fiber length of 20 km is proposed.
SUMMARY OF THE INVENTION
The object of the present invention is to improve on the method so that the measurement results are improved with a simpler and miniaturized measuring system.
This object is achieved with the signal shape of the injection current which has a steep rising edge compared to its pulse length and a subsequent plateau. Surprisingly, this laser control having steep rising edges and a subsequent plateau, contrary to the usual laser control used for modifying frequencies, results in improved heterodyne interferometric measurement with the optical path diminishable to less than 1 cm. Thus the coherence function of the interference signal contrast can be substantially improved, resulting in a measurement signal that is easier to evaluate. At the same time, the dimensions of the system are considerably reduced and, for example, a considerably smaller bypass prism can be used to miniaturize the measuring system. This is an important advantage, for example, in the case of multidimensional measurements with a plurality of measuring channels, such as those performed with a multi-axis vibrometer. A test model has shown that the dimensions can be reduced several times compared to conventional measurement systems. As an additional advantage, the system can be made insensitive to back reflexes, with the length of the optical bypass being accurately set within narrow tolerances, so that exact evaluations are obtained even with a multimode interference signal in the region of a peak of the coherence function without the need for elaborate measures to suppress back reflexes. Narrow tolerances of the optical bypass can be easily observed with the small overall length of the optical bypass, which is on the order of 1 mm, for example. In order to eliminate the instability of the interference signal at the steep pulse edges during evaluation, the signal converted in a photoelectric transducer of the measuring receiver is advantageously evaluated with a delay during the plateau, only after the edge of the injection current appears.
A simple signal shape is, for example, rectangular pulses of the injection current, which results in extremely steep edges compared to the total pulse length. Relatively steep edges of the signal shape can, however, also be obtained using trapezoidal pulse shapes, pulse shapes that are sinusoidal at the edges, or similar shapes with a plateau.
One advantageous mode of operation is when the injection current pulsates between a minimum value that is less than the threshold current of the laser and a maximum value that is greater than the threshold current. Thus no radiation is emitted during the pauses between pulses. As an alternative, the injection current may pulsate between a minimum value that is greater than the threshold current of the laser and a greater maximum value. In this operating mode, the laser continuously emits radiation whose frequency varies.
In order to eliminate the instability of the interference signal at the steep pulse edges during evaluation, the signal converted in a photoelectric transducer of the measuring receiver is advantageously evaluated with a delay during the plateau, only after the edge of the injection current appears.
The method can be advantageously used so that a plurality of such laser signals are related to form a plurality of measurement channels in time-multiplex mode, with the heterodyne signals of the different measurement channels being generated in non-overlapping time windows. The different channels can be easily evaluated separately using multiplex mode in the evaluation circuit. For simple design and simple evaluation, the laser control signals are advantageously delivered by a common control circuit, and laser diodes, each assigned to one measuring channel, are provided, and a photoelectric transducer that is common to the measurement channels is provided, from which the signals are received in the time multiplex mode and are evaluated separately fo
Kenyon & Kenyon
Kim Robert
Robert & Bosch GmbH
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