RU2054639C1 - Fabry-perot optical filter - Google Patents

Abstract

FIELD: optical instrument making. SUBSTANCE: stabilization of optical length of an interval between mirrors of an interferometer is provided by sustaining a constant spatial position of maximums of an interference pattern of irradiation of a reference source at an output of the above mentioned interferometer. That allows to eliminate using a while light source, a modulator and one of correction units and to significantly simplify the other correction unit. EFFECT: simplified structure of filters. 1 cl, 1 dwg

Description

 The invention relates to technical physics, in particular to optical instrumentation, is intended for long-term observations of astronomical sources at a given wavelength and can be used in meteorology, nuclear research and spectral studies of laboratory sources.

Known optical filter containing a white light source, a light splitter, auxiliary and main Fabry-Perot interferometers and three photodetectors, as well as electronic systems for monitoring the parallelism of the plates and the working interval of the main interferometer. The auxiliary interferometer includes two mirrors rigidly interconnected and located at an angle α to the optical axis. The radiation of the white light source used for control is modulated by modulating the length of the working gap of the auxiliary interferometer when it rotates around the axis. The main Fabry-Perot interferometer includes a fixed mirror and a moving mirror, around which three piezoelectric elements are fixed. Each of the three outputs of the light splitter through the main interferometer is optically connected to the input of the corresponding photodetector, the output of which is connected to the corresponding input of the electronic control system, while the outputs of the system are connected to the inputs of the corresponding piezoelectric elements. The installation of the auxiliary interferometer in angle is used to adjust the transmission wavelength of the main interferometer. To eliminate the influence of ambient temperature changes on the stability of the device housing additionally applied with temperature control within 0.1 ^° C Stabilizing optical length of the working gap between the plates of the main interferometer is provided by comparing it with the length of the working gap of the auxiliary interferometer, the relative stability of the transmission frequency of the fundamental interferometer d ν / ν10 ^-5 10 ^-6 . The low stability of the filter is associated with the mechanical rotation of the auxiliary interferometer and the absence of a highly stable reference standard, which leads to insufficient stability of the transmission frequency of the main Fabry-Perot interferometer. In addition, temperature control complicates the device.

Known optical filter containing a Fabry-Perot interferometer, a reference capacitor, three bridge electronic circuits and three operational amplifiers. One of the mirrors of the interferometer is mounted on three piezoelectric elements. On the inner side of the mirrors, five pairs of conductive pads forming five capacitors are sprayed. The parallelism of the mirrors is ensured by comparing the capacities of these capacitors with the capacity of the reference. The advantage of this solution is the lack of a control beam and an auxiliary interferometer. The maximum relative accuracy of maintaining the parallelism of the mirrors and the length of the working interval of the interferometer in the implemented solution is d ν / ν10 ^-5 10 ^-6 . The insufficient stability of the transmission frequency of the optical filter is associated with the low stability of the capacitance of the reference capacitor. In addition, changes in the dielectric constant of the air in the reference capacitor and the refractive index of the air gap between the plates of the interferometer depending on atmospheric pressure, temperature and humidity are not unambiguous, which leads to additional filter instability.

Known spectrometer designed for infrared radiation. The spectrometer contains a white light source, a monochromator, a beam splitter, the primary and secondary Fabry-Perot interferometers, as well as systems for electronic control and correction of the parallelism of plates and the length of the working gap of the main interferometer. The case, in which the main interferometer is placed, is cooled and evacuated. The optical length of the working gap between the plates of the main interferometer is stabilized by comparing it with the length of the working interval of the auxiliary interferometer, while the relative stability of the transmission frequency of the main interferometer is d ν / ν10 ^-4 10 ^-5 . The low stability of the transmission frequency of the main Fabry-Perot interferometer is associated with the absence of a highly stable reference standard, and the use of cryogenic techniques and vacuumization to reduce instrument noise and the influence of atmospheric parameters complicates the spectrometer.

A known spectrometer designed to perform comparative studies of uranium isotopes by the optical spectra method. The spectrometer contains a reference radiation source, a light beam splitter, a Fabry-Perot interferometer, as well as a sawtooth voltage generator, an interference pattern phase meter and an electronic control system for the length of the interferometer working gap. Stabilization of the length of the working interval of the interferometer is achieved by controlling the phases of the interferograms of the radiation of the reference source through active feedback, which allows to achieve relative stability d ν / ν10 ^-7 10 ^-8 . Using the spectrometer as an optical filter for long-term observations at a given frequency leads to a loss of information due to the need for a monitoring system to function in the constant scanning mode.

The prototype, based on a set of similar essential features, adopted the Fabry-Perot optical filter developed at NIRFI, containing a reference radiation source and a white light source optically coupled through the addition unit, with which a beam expander made in the form of a capacitor, a diaphragm connected in series, was connected with a shaper of modulating voltage frequency modulator and dividing mirror. The dividing mirror performs the function of a spectrum divider and, along the first beam, is optically coupled through a monochromator to a series-mounted light splitter and a Fabry-Perot interferometer. In the course of the second beam, the dividing mirror is connected to the signal input of the first correction unit, the output of which is connected to the correlation input of the modulator. The Fabry-Perot interferometer includes a fixed mirror and a moving mirror, around which three piezoelectric elements are fixed. Each of the three outputs of the light splitter is optically connected to the corresponding signal input of the second correction unit, the outputs of which are connected to the corresponding piezoelectric elements of the Fabry-Perot interferometer. The reference input of the correction unit is connected to the output of the synchronization unit, also connected to the reference inputs of the first correction unit and the modulating voltage driver. An auxiliary Fabry-Perot interferometer is used as a frequency modulator. It includes two mirrors, one of which has a piezoelectric element mounted. The optical filter prototype has the highest frequency stability among known optical filters of this type. Theoretically, its instability is determined by the instability of the frequency of the reference source. When using a frequency-stabilized laser with an instability d ν / ν = 10 ^-8 10 ^{-9, the} instability of the filter transmission frequency should have the same value. The filter provides for the possibility of tuning the transmission frequency.

 However, when analyzing high-frequency processes with a characteristic time of ≈ 0.001 s (for example, processes in a plasma, luminescence of liquids and gases under the influence of external pathogens, processes in an electric arc, etc.), fluctuations in the radiation intensity as a white light source take place, and the source of laser radiation does not allow in practice to realize the theoretical stability of the transmission frequency of the filter.

Indeed, the phase ψ _{i of the} signal at the output of each channel of the second correction block associated with the main Fabry-Perot interferometer has the form
ψ _i = ψ ₁ + ψ '+ δ ψ _I + δ ψ ₁ , where ψ ₁ is the phase component resulting from the passage of white light radiation through the Fabry-Perot auxiliary interferometer, the instability of this component is determined by the frequency instability of the reference source;
ψ 'component of the phase arising due to the passage of radiation of a white light source through the main Fabry-Perot interferometer, the instability of this component is determined by the instability of the frequency of the reference source;
δ ψ _I phase fluctuations caused by fluctuations in the radiation intensity of the white light source, arising from the passage of this radiation through the main Fabry-Perot interferometer;
δ ψ ₁ phase fluctuations caused by fluctuations in the radiation intensity of the reference source that occur when the radiation of a white light source passes through an auxiliary Fabry-Perot interferometer.

Estimates show that the presence of phase components δ ψ _I and δ ψ ₁ in the above cases worsens the real stability of the filter transmission frequency by 1-2 orders of magnitude compared to the theoretical one. In addition, the use of a white light source requires special measures for its cooling, which significantly complicate the design. The absence of these measures leads to additional instability of the optical filter. The presence of a modulator contributes to the emergence of communication with the external environment through the acoustic field created by it. This leads to uncontrolled environmental influences on the optical elements of the filter, reducing the achievable stability.

 The problem to which the invention is directed is the development of a Fabry-Perot optical filter, in which, while simplifying the design, high transmission frequency stability is ensured in the analysis of both low-frequency and high-frequency processes.

 The developed Fabry-Perot optical filter contains optically coupled reference radiation source, a slit diaphragm, and a Fabry-Perot light splitter and interferometer sequentially located on the optical axis, including a fixed mirror and a moving mirror. Three piezoelectric elements are fixed along the perimeter of the moving mirror. Each of the three outputs of the light splitter is optically coupled to a corresponding signal input of the correction unit. The outputs of the correction unit are connected to the corresponding piezoelectric elements, and the reference inputs are connected to the corresponding tunable sources of reference voltage. The correction block includes three operational amplifiers, the outputs of which are the corresponding outputs, and the non-inverting inputs are the corresponding reference inputs of the correction block.

 New in the developed Fabry-Perot optical filter is that a second and third slotted diaphragms are introduced into it. Each slit diaphragm is mounted on the corresponding signal input of the correction unit. The correction unit includes the first, second and third coordinate indicators, the input of each of which is the corresponding input of the correction unit, and the output is connected to the inverting input of the corresponding operational amplifier. The light splitter is installed directly behind the reference radiation source.

10^-9-10^-10
Это в свою очередь позволяет использовать источник эталонного излучения повышенной стабильности.The essence of the invention lies in the fact that the stabilization of the optical length of the gap between the mirrors of the interferometer is ensured by maintaining a constant spatial position of the maxima of the interference pattern of the radiation of the reference source at the output of the specified interferometer. This eliminates the white light source, the modulator, and one of the correction blocks, and significantly simplifies the other correction block. Since the line identification accuracy provided by the coordinate indicator is ≈10 ^-5 10 ^-6 of the interferogram period, and the optical gap length is 10 ⁴ wavelengths of the reference radiation, the resulting relative line identification accuracy is

10 ^-9 -10 ^-10
This in turn allows the use of a source of reference radiation of increased stability.

 The drawing shows a structural diagram of an optical filter Fabry-Perot.

 The Fabry-Perot optical filter contains a reference radiation source 1, a light splitter 2, and a Fabry-Perot interferometer 3 sequentially mounted on the optical axis. The interferometer 3 includes a fixed mirror 4 and a movable mirror 5, along the perimeter of which three piezoelectric elements are mounted 6. Each of the three outputs of the light splitter 2 is optically coupled through the interferometer 3 and the corresponding slot diaphragm 7 to the corresponding signal input of the correction unit 8. Block 8 includes the first, second, and third coordinate indicators 9, the input of each of which is the corresponding signal input of block 8. The output of each coordinate indicator 9 is connected to the inverting input of the corresponding operational amplifier 10. Non-inverting inputs of operational amplifiers 10 are the reference inputs of block 8 and are connected to the corresponding tunable sources 11 of the reference voltage. The outputs of the operational amplifiers 10 are the outputs of block 8 and are each connected to a corresponding piezoelectric element 6.

As source 1, a frequency-stabilized laser can be used, for example, of the LNG-302 type with frequency instability d ν / ν10 ^-8 10 ^-9 . The light splitter 2 can be made in the same way as in the prototype, which contains an optically coupled collecting short-focus lens that collects a long-focus lens, a screen with three round holes and three identical rotary mirrors mounted each opposite the corresponding screen opening at an angle π / 4 to the optical axis of the light splitter. As the piezoelectric elements 6 can be used standard, for example, type LU-5. Correction block 8 is intended for generating correction signals for the optical length of the gap between the mirrors 4, 5 of the interferometer 3. As coordinate indicators 9, coordinate indicators of the energy center of the light spot according to ed. St. USSR N 1106425, 1985. Tunable sources of reference voltage 11 are designed to generate voltage pre-filter, as well as tuning the transmission frequency.

 The stabilization of the transmission frequency in the optical Fabry-Perot filter is as follows.

 The light splitter 2 converts the diverging radiation beam of the reference source 1 into three beams passing through the interferometer 3. The interferometer generates an interferogram of the radiation of the source 1. The diaphragm 7 in each channel provides the allocation of one maximum interference pattern. Block 8 in each channel provides, when changing the optical length of the gap between the mirrors 4, 5, the formation of the corresponding signal of correction. This is as follows.

 Changing the optical length of the gap between the mirrors 4, 5 leads to a shift of the maxima of the interference pattern, and therefore to a change in the spatial position of the energy center of the light spot on the photosensitive element of the coordinate indicator 9. The voltage generated at the output of the coordinate indicator 9 corresponds to the spatial position of the energy center of the light spot on the photosensitive element, therefore, a change in the latter causes a change in the specified voltage. Since the steady state of the correction circuit corresponds to the equality of the voltages at the inputs of the operational amplifier 10, a change in voltage at its inverting input leads to the appearance of a correction signal at its output, i.e. at the output of block 8. This signal is applied to the corresponding piezoelectric element, as a result of which the optical length of the gap between the mirrors is adjusted. The presence of three correction channels ensures the stability of the optical length of the gap between the mirrors 4, 5 of the interferometer 3 over the entire working field and thereby stabilizes the filter transmission frequency. The tuning of the filter transmission frequency is carried out by changing the voltage at the non-inverting input of the operational amplifier 10.

Claims (1)

 FABRY OPTICAL FILTER - PERO, containing optically coupled reference radiation source, a slit diaphragm and a light splitter and a Fabry-Perot interferometer sequentially located on the optical axis, including a fixed mirror and a movable mirror, three piezoelectric elements are fixed along the perimeter, with each of the three outputs of the light splitter optically connected to the corresponding signal input of the correction unit, the outputs of which are connected to the corresponding piezoelectric elements, and the reference inputs the holes are connected to the corresponding tunable sources of the reference voltage, and the correction unit includes three operational amplifiers, the outputs of which are the corresponding outputs, and the non-inverting inputs are the corresponding reference inputs of the correction unit, characterized in that the second and third slotted diaphragms are additionally introduced into it, at each slit diaphragm is mounted on the corresponding signal input of the correction unit, which includes three coordinate indicators, the input of each of which is corresponding signal input of the correction unit, and the output is connected to the inverting input of the corresponding operational amplifier, and the light splitter is installed directly behind the reference radiation source.

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