RU208574U1 - DEVICE FOR FILTERING THE SPECTRA OF OPTICAL SIGNALS - Google Patents

Abstract

The device for filtering the spectra of optical signals belongs to the field of optical instrumentation and optoelectronics and is designed to filter optical radiation in the visible and near infrared ranges of optical radiation. The device contains a variable depth diffraction grating with a linearly changing relief depth (2) located on a turntable (4) , as well as a spatial filter (3). The diffraction grating is a mirror-reflecting relief periodic diffraction structure with a variable linear relief depth, having a high reflection coefficient, with a rectangular meander-type relief, on which relief lines with a linearly varying relief depth exceeding the wavelength of the input optical radiation are applied. The reflective relief periodic diffractive structure is fixed on a turntable, which is installed on a fixed base (7) and is connected to the mechanism for adjusting the angle of incidence (5) of the light beam (1) on the turntable, and is also connected to the movement mechanism (6) of the relief structure for linear changes in the depth of the grating. The plane of incidence of the light beam on the reflective relief periodic diffractive structure is parallel to the relief lines of the diffractive structure. The device operates as follows. Optical radiation is incident on the diffraction grating at an angle θ in a certain zone with a fixed relief depth, which is located parallel to the lines of the grating relief. With the help of pre-calculated filter indicators, the radiation is tuned to the calculated frequency. The technical result consists in increasing the number of isolated individual spectral lines with an increased optical radiation power transfer coefficient from the device input to its output by smoothly changing the depth of the reflective diffractive relief structure and changing the angle of the incident beam.

Description

The utility model relates to the field of optical instrumentation and optoelectronics and is intended for filtering optical radiation in visible and near infrared radiation.

An analogue of this technical solution is known from the existing level of technology, referred to as a device for filtering spectra of optical signals. [RF patent No. 2018107980, 05.03.2018. A device for filtering spectra of optical signals // Patent of Russia №181381 U1. 2018./ Komotskiy V.A., Sokolov Yu.M., Suetin N.V.].

The device contains a diffraction grating of constant depth, located on a turntable, as well as a spatial filter. The diffraction grating is a specularly reflecting relief periodic diffraction structure with a constant relief depth, having a high reflection coefficient, with a rectangular relief of the meander type, with a constant relief depth H exceeding the wavelength of the input optical radiation λ. The reflective relief periodic diffraction structure is installed on a turntable, which is connected with a mechanism for adjusting the angle of incidence of the light beam. The plane of incidence of the light beam on the reflecting relief periodic diffraction structure is parallel to the relief lines of the diffraction structure.

The device works as follows. The optical radiation of the laser is incident on the diffraction grating at an angle θ parallel to the direction of the grating relief. After reflection from a relief periodic diffraction structure, only the zero diffraction order is separated using a spatial filter; the spatial filter is located at a fixed distance sufficient to separate the beams of the zero and higher diffraction orders separately. The radiation power factor in the zeroth diffraction order, which depends on the depth of the reflecting diffractive structure and on the angle of incidence of the input optical beam, must correspond to the maximum value to isolate the most intense spectral emission line, while overlapping other spectral lines. The technical result consists in increasing the coefficient of power transmission of optical radiation from the input of the device to its output when filtering certain wavelengths of optical radiation by changing the angle of the incident beam.

The disadvantage of the device for filtering the spectra of optical signals is the limited range of the device due to the fixed depth of the reflective relief periodic diffraction structure.

The closest in technical essence is a spatial filter for laser radiation and a device for forming laser radiation of diffraction quality with its use [Dolgopolov I.S. Optical filter based on deep relief structure of variable depth / Dolgopolov I.S., Petrova M.S., Syuy A.V. // Proceedings of the XI International Conference "Fundamental Problems of Optics -2019". -2019. S. 103-105.].

The device contains a diffraction grating of variable depth, located on a turntable, and a spatial filter. The diffraction grating is a specularly reflecting relief periodic diffraction structure with a variable relief depth, having a high reflection coefficient, with a rectangular shape of the meander-type relief, with four zones, each of which has relief lines with certain relief depths exceeding the wavelength of the input optical radiation. The reflective relief periodic diffraction structure is installed on a turntable, which is connected with the mechanism for adjusting the angle of incidence of the light beam, and also connected with the mechanism of movement of the relief structure to change the grating depth, which has different values in each of the four zones. The plane of incidence of the light beam on the reflecting relief periodic diffraction structure is parallel to the relief lines of the diffraction structure.

The device works as follows. Optical radiation is incident on the diffraction grating at an angle θ to one of four zones with a fixed relief depth, which is located parallel to the grating relief lines. Further, when reflecting from a relief structure using a spatial filter, the zero diffraction order is distinguished. The pre-calculated filter values are used to tune the radiation to the calculated frequency. The radiation power factor in the zeroth diffraction order, which depends on the depth of the reflecting diffractive structure and on the angle of incidence of the input optical beam, must correspond to the maximum value to isolate the most intense spectral emission line, while overlapping other spectral lines. The technical result consists in increasing the coefficient of transmission of optical radiation power from the input of the device to its output when filtering certain wavelengths of optical radiation with a change not only in the angle of incidence of the input radiation, but also due to a discrete change in the depth of the relief of the diffraction grating.

The disadvantage of the device is a limited (discrete) set of selected spectral lines due to a stepwise change in the deep regular diffraction structure.

The problem to be solved by the claimed device is to increase the power transmission coefficient of optical radiation from the input of the device to its output with an increased number of separated individual spectral lines.

This technical problem is solved due to the fact that the optical filter is made using a deep relief structure (diffraction grating) of variable linear depth, changing linearly.

The device for filtering the spectra of optical signals (Fig. 1) contains a diffraction grating (2) of variable depth with a linearly varying depth of the relief (Fig. 2), located on a turntable (4), as well as a spatial filter (3). The diffraction grating is a specularly reflecting relief periodic diffractive structure with a variable linear relief depth, having a high reflection coefficient, with a rectangular shape of the meander-type relief, on which relief lines are applied with a linearly varying relief depth exceeding the wavelength of the input optical radiation. The reflective relief periodic diffractive structure is fixed on a turntable, which is installed on a fixed base (7) and is connected to the mechanism for adjusting the angle of incidence (5) of the light beam (1) on the turntable, and is also connected to the mechanism of movement (6) of the relief structure for linear changes in grating depth. The plane of incidence of the light beam on the reflecting relief periodic diffraction structure is parallel to the relief lines of the diffraction structure.

The device works as follows. Optical radiation is incident on the diffraction grating at an angle θ to a certain zone with a fixed relief depth, which is located parallel to the grating relief lines. Using the pre-calculated filter values according to formula (1), the radiation is tuned to the calculated frequency.

where k _p is the radiation power factor; H _p is the depth of the relief at the point of incidence of the input radiation; λ _p is the radiation wavelength; θ _p is the angle of incidence of the input radiation.

The radiation power factor in the zeroth diffraction order, which depends on the depth of the reflecting diffractive relief structure and on the angle of incidence of the input optical beam, must correspond to the maximum value to isolate the most intense spectral emission line, while overlapping other spectral lines. The coefficient of the most intense spectral line should be close to 1, and the coefficient of the other should tend to zero. Thus, equation (1) for the most intense spectral line takes the following form:

We derive the variable λ _p for both cases:

For example, with the parameters: depth of the relief H _p = 6 microns, the angle of incidence of the beam θ _p = 58.5 °, the input radiation can be tuned to the required frequency so as to select one of the most intense spectral lines of radiation, and overlap the others. In the visible range of radiation, the wavelengths for these parameters correspond to the values:

In this case, the spectral line with the wavelength λ ₁ = 0.57 μm and the frequency v ₁ = 525.9 THz has the maximum intensity, and the spectral line with the wavelength λ ₂ = 0.6 μm and the frequency v ₂ = 454.2 THz overlaps ... FIG. 3, the graph shows the overlap of the most intense spectral line by another, less intense one.

This device can be used not only in the visible light range, but also in the infrared range. By reconfiguring the device to the parameters: relief depth H _p = 6 microns, the angle of incidence of the beam θ _P = 30.4 °, it is possible to tune the input radiation in the infrared range to the required frequency so as to select one of the most intense spectral lines of radiation, and overlap the others. In the infrared range of radiation, the wavelengths with these parameters correspond to the values:

In this case, the spectral line with the wavelength λ ₁ = 1.38 μm and the frequency v ₁ = 217.2 THz has the maximum intensity, and the spectral line with the wavelength λ ₂ = 0.9 μm and the frequency v ₂ = 333.1 THz overlaps. FIG. 4, the graph shows the overlap of the most intense spectral line by another, less intense one.

The technical result consists in increasing the number of separated individual spectral lines with an increased coefficient of power transmission of optical radiation from the input of the device to its output due to a smooth change in the depth of the diffraction grating and changes in the angle of the incident beam. At different angles of incidence, zero transmission coefficients of the filter correspond to different wavelengths. By changing the angle of incidence of the input radiation and the depth of the relief, it is possible to change the reflected frequency characteristics of optical radiation with the maximum transmission coefficient (close to unity) in a wide spectral range.

The advantage of the inventive device for filtering optical radiation is that the depth of the diffraction grating changes according to a linear law, thereby providing a multitude of separated individual spectral lines with an increased coefficient of power transmission of optical radiation from the input of the device to its output, which will make it possible to more accurately adjust the input radiation.

Claims (1)

The device for filtering spectra of optical signals contains a diffraction grating of variable depth with a linearly varying depth of relief, fixed on a turntable, which is installed on a fixed base and is connected with a mechanism for adjusting the angle of incidence of a light beam on a turntable, and is also associated with the mechanism of movement of the relief structure for linear changes in the grating depth, a spatial filter, and the diffraction grating is a specularly reflecting relief periodic diffraction structure with a variable linear relief depth of the meander type, on which relief lines with a linearly varying relief depth are drawn.

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