RU217959U1 - DEVICE FOR SIMULATION OF PHONO-TARGET ENVIRONMENT - Google Patents

Abstract

The utility model relates to control and measuring equipment in optoelectronic instrumentation, is intended to simulate the background-target environment for the study and evaluation of the characteristics of two-spectrum optoelectronic systems (OES) operating in different wavelength ranges, and can be used to develop detection algorithms , selection and maintenance of objects of registration. The device contains the first controller connected to the first DMD-matrix, equipped with an illumination unit with the radiation of the first spectrum range, and the first optical system for transmitting the radiation flux from the first DMD-matrix. The device includes a second controller connected to the second DMD-matrix, equipped with an illumination unit with radiation of the second spectrum range, a second optical system for transmitting the radiation flux from the second DMD-matrix, and a unit for matching the optical radiation fluxes of the first and second spectrum ranges, made with the possibility of their transmission to the input of the optical-electronic system under study, while the first and second optical systems for transmitting radiation fluxes are made in the form of collimating lenses of the corresponding spectral ranges, having the same focal lengths and optically coupled to the matching unit of optical radiation fluxes of the first and second spectral ranges, and the inputs of the first and second controllers are configured to connect to an external control unit and form a digital scene model. EFFECT: expanding the functionality of the simulation device by providing the formation of a phono-target environment in two different wavelength ranges. 3 w.p. f-ly, 2 ill.

Description

The utility model relates to control and measuring equipment in optoelectronic instrumentation, is intended to simulate the background-target environment for the study and evaluation of the characteristics of two-spectrum optoelectronic systems (OES) operating in different wavelength ranges, and can be used to develop detection algorithms , selection and maintenance of objects of registration.

The analogue is an infrared environment simulation system containing a dynamic scene generator, including a bank of images of test objects, a bank of underlying surface properties, a bank of dynamic parameters, a block of geometric transformations, a block of signs of the appearance of target objects, a bank of physical properties of objects, a bank of physical properties of the atmosphere , an image synthesis unit, a visible image converter, including a converter, a broadband infrared radiation source, an infrared radiation spectrum control unit, a unit for converting infrared illumination phase modulation into amplitude modulation, a recognition and certification unit, including an optical unit for transferring the synthesized image, a thermal imaging receiver under study, a unit metrological certification, recognition unit, signature extraction unit (Patent RU 2713614, IPC G06G 7/48, published on 02/05/2020).

The prototype is an infrared (IR) environment simulation system for mathematical modeling, characterized in that it contains a control unit configured to download data about an object in the form of a mathematical model by creating a set of digital data, and transmitting this data via a cable communication channel to a controller associated with DMD-matrix (Digital Micromirror Device), configured to display on the field of this matrix in graphic form an image of a mathematical model of an object, a device for illuminating the indicated image with infrared radiation on the field of the DMD-matrix, with which the optical system for transmitting the radiation flux is connected in the form of a projection device for transmission of these data from aperture to aperture of the studied thermal imaging receiver operating in the infrared radiation spectrum (Patent RU 2513674, IPC G06G 7/48 published on April 20, 2014).

The disadvantages of the analogue and prototype are limited functionality due to work in only one infrared wavelength range, which makes it impossible to use this system to study and evaluate the characteristics of two-spectrum OES.

The task to be solved by the utility model is to expand the functionality of the simulation device by providing the formation of a background-target environment in two different wavelength ranges.

The problem is solved due to the fact that in the device for simulating the background-target environment, containing the first controller connected to the first DMD matrix, equipped with an illumination unit with radiation from the first spectrum range, and the first optical system for transmitting the radiation flux from the first DMD matrix, according to the present utility model, additionally introduced is a second controller connected to the second DMD-matrix, equipped with an illumination unit with radiation of the second spectrum range, a second optical system for transmitting the radiation flux from the second DMD-matrix and a unit for matching the optical radiation fluxes of the first and second spectrum ranges, made with the possibility of their transmission to the input of the optoelectronic system under study, while the first and second optical systems for transmitting radiation fluxes are made in the form of collimating lenses of the corresponding spectral ranges, having the same focal lengths and optically coupled to the matching unit of optical radiation fluxes of the first and second spectral ranges, and the inputs of the first and the second controllers are configured to be connected to an external control unit and form a digital scene model.

And also by the fact that the block for matching the optical radiation fluxes of the first and second ranges of the spectrum is made in the form of a dichroic mirror installed at an angle of 45° to the optical axes of the collimating objectives.

And also by the fact that the block for matching optical radiation fluxes of the first and second ranges of the spectrum is made in the form of a triangular optical prism with two reflective side leg faces and two flat mirrors installed parallel to the corresponding faces of the prism and associated with the exit pupils of the corresponding collimating lenses.

And also by the fact that the block for matching the optical fluxes of radiation of the first and second ranges of the spectrum is made in the form of two pairs of flat mirrors installed in the course of the rays of the corresponding collimating lenses at an angle of 45 ° to their optical axes and perpendicular to each other, while the second in the direction of the rays mirrors in pairs are installed with the possibility of moving along the optical axis of the corresponding radiation flux in the areas between the mirrors in a pair.

The figure 1 shows a functional diagram of the proposed device for simulating the background-target environment.

Figure 2 (a, b, c) shows the optical schemes of the block for matching the optical radiation fluxes of the first and second ranges of the spectrum.

The device for simulating the background-target environment contains the first controller 1 connected to the first DMD-matrix 2, equipped with the illumination unit 3 with the radiation of the first spectrum range, with which the first optical system 4 for transmitting the radiation flux 5 from the first DMD-matrix 2 is connected.

The difference of the proposed device is that the second controller 7 is additionally introduced, connected to the second DMD-matrix 8, equipped with an illumination unit 9 with radiation of the second spectrum range and forming the corresponding radiation flux, the second optical system 10 for transmitting the radiation flux 11 from the second DMD-matrix 8 and unit 12 for matching optical radiation fluxes of the first and second ranges of the spectrum, configured to transmit the matched radiation flux 13 to the input of the studied OES 6.

The inputs of the first 1 and second 7 controllers are configured to connect to an external control unit 14 and form a digital scene model.

Block 14 is made in the form of a control device with installed special software for downloading and generating a simulated background-target environment.

The first 1 and second 7 controllers are DMD controllers with a processed image resolution of 1920 × 1080 pixels to control the pulse-width modulation of optical streams, respectively 5 and 11.

The first 2 and second 8 DMD matrices are blocks of movable micromirror modulators controlled by the respective controllers 1 and 7, with the ability to display on them in graphical form an image of a mathematical model of background-target environment scenarios in the optical wavelength range.

By modulating radiation from illumination nodes 3 and 9, micromirrors create a given distribution of energy at specific points of the focal plane of optical systems 4 and 10 for transmitting radiation fluxes, thereby simulating real optical fluxes of optical radiation from target objects and the background.

DMD matrices 2 and 8 are made in the form of a DLP 9500 matrix with protective windows that are transparent in the operating wavelength range.

Nodes 3, 9 illumination of the first and second DMD matrices 2, 8 are optical systems with radiation sources in the required operating range of the spectrum, providing uniform illumination of DMD matrices.

The first 4 and second 10 optical transmission systems, respectively, of the radiation fluxes of the first and second ranges of the spectrum are made in the form of collimating lenses corresponding to the spectral ranges, having the same focal lengths to match the radiation fluxes of the first and second ranges of the spectrum with the same increase at the input and output of block 12 agreement.

Block 12 for matching optical radiation fluxes of the first and second ranges of the spectrum can be made in the form of a dichroic mirror installed at an angle of 45° to the optical axes of the collimating lenses of optical systems 4 and 10 (Fig. 2a).

The block 12 for matching optical radiation fluxes of the first and second ranges of the spectrum can be made in the form of a triangular optical prism 15 with two reflective side leg faces and two flat mirrors 16 and 17 installed parallel to the corresponding faces of the prism 15 and associated with the exit pupils of the corresponding collimating lenses (Fig. .2b).

The block 12 for matching the optical fluxes of radiation of the first and second ranges of the spectrum can be made in the form of two pairs of flat mirrors 16, 18 and 17, 19, installed in the course of the rays of the corresponding collimating lenses at an angle of 45 ° to their optical axes and perpendicular to each other, with In this case, the mirrors 18 and 19 second in the direction of the rays in pairs are installed with the possibility of moving along the optical axis of the corresponding radiation flux in the areas between the mirrors in a pair (Fig. 2c).

Mirrors 16 and 17 are rigidly fixed and set at an angle of 45° to the optical axes of the collimating objectives of optical systems 4 and 10.

Mirrors 16 and 17 direct the radiation fluxes of the first and second ranges of the spectrum from optical systems (collimation lenses) 4 and 10 to mirrors 18 and 19, respectively.

Mirrors 18 and 19 are installed with the possibility of moving along the optical axes of the corresponding radiation fluxes in the areas between the mirrors in pairs 16-18 and 17-19, which provides regulation of the distance between the optical radiation fluxes of the first and second spectral ranges leaving the device for optimal matching with the optical inputs. channels of the investigated UES 6.

The proposed phono-target environment simulation device is designed to reproduce the graphic form of the image of the mathematical model of the phono-target environment scenarios in the form of an optical stream 13 in two different optical ranges at the input of the studied two-spectral OES 6 and can be used to study two-spectral OES operating in various combinations of spectrum ranges : visible, near-IR, short-wave IR, mid-IR, long-wave IR, mainly in visible and mid-IR, visible and long-wave IR.

The phono-target situation simulator works as follows.

Data about target objects and background in the form of a mathematical model is loaded into the block 14 for controlling and forming a digital model of the scene by creating a set of input digital data for background-target environment scenarios, which are transmitted via cable communication channels to controllers 1 and 7, which control DMD matrices, 2 and 8, respectively, and set the elements of the DMD matrices to different modulation frequencies of the radiation in accordance with the frequency-contrast characteristic of the image.

Illumination nodes 3, 9 illuminate the corresponding DMD matrices 2, 8 with radiation from the first and second operating ranges of the spectrum.

The radiation of the first working range of the spectrum, reflected from the elements of the DMD-matrix 2, having different modulation frequencies, reproduces a contrast image of the background-target environment in the first range of the spectrum, and the radiation of the second range of the spectrum, reflected from the elements of the DMD-matrix 8, having different modulation frequencies, reproduces a contrast image of the background-target environment in the second range of the spectrum.

Through the optical system 4 for transmitting the radiation flux, which is a collimating lens, the graphic form of the image of the background-target environment in the form of an optical flux 5 of the radiation of the first range of the spectrum is transferred to the block 12 for matching optical radiation fluxes.

Through the optical system 10 for transmitting the radiation flux, which is also a collimating lens, the graphic form of the image of the background-target environment in the form of an optical radiation flux of the second range of the spectrum 11 is transferred to the radiation matching unit 12.

Due to the implementation of the collimating lenses of the optical systems 4, 10 transmission of radiation fluxes with the same focal lengths, matching of the radiation fluxes of the first and second ranges of the spectrum with the same increase at the input and output of the matching unit 12 is achieved.

Block 12 for matching radiation from optical systems 4 and 10 for transmitting streams 5, 11, respectively, of the first and second ranges of the spectrum, directs these optical streams to the input of the studied thermal television OES 6.

The execution of the block 12 for matching radiation according to the variant shown in figure 2a allows the device to be used to study thermal television systems 6 with a common entrance pupil for its optical channels.

The execution of the block 12 matching the radiation according to the variant shown in figure 2b, allows you to use the device for the study of thermal television systems 6 with optical channels located at a fixed distance from each other.

The execution of the radiation matching block 12 according to the variant shown in figure 2c, due to the movement of the second mirrors 18 and 19 along the optical axis of the corresponding radiation flux in the areas between the mirrors 16-18 and 17-19 in the corresponding pairs, makes it possible to use the device for studying two-spectrum systems 6 with optical channels located at different distances from each other.

Thus, the implementation of the device for simulating the phono-target environment in accordance with the proposed technical solution allows expanding its functionality by providing the formation of the phono-target environment in the two required spectral ranges for studying the characteristics of two-spectral optoelectronic systems.

Claims (4)

1. A device for simulating a background-target environment, containing a first controller connected to the first DMD matrix equipped with an illumination unit with radiation from the first spectrum range, and a first optical system for transmitting the radiation flux from the first DMD matrix, characterized in that a second controller connected to to the second DMD-matrix, equipped with an illumination unit with radiation of the second spectral range, a second optical system for transmitting the radiation flux from the second DMD-matrix and a unit for matching optical radiation fluxes of the first and second spectral ranges, configured to transmit them to the input of the optoelectronic system under study, in this case, the first and second optical systems for transmitting radiation fluxes are made in the form of collimating lenses of the corresponding spectral ranges, having the same focal lengths and optically coupled to the matching unit of optical radiation fluxes of the first and second spectrum ranges, and the inputs of the first and second controllers are made with the ability to connect to an external control unit and formation of a digital scene model. 2. A device for simulating a phono-target environment according to claim 1, characterized in that the block for matching the optical fluxes of radiation of the first and second ranges of the spectrum is made in the form of a dichroic mirror installed at an angle of 45 ° to the optical axes of the collimating lenses. 3. The device for simulating the phono-target environment according to claim 1, characterized in that the block for matching optical radiation fluxes of the first and second ranges of the spectrum is made in the form of a triangular optical prism with two reflective side leg faces and two flat mirrors installed parallel to the corresponding faces of the prism and associated with the exit pupils of the corresponding collimation objectives. 4. The device for simulating the phono-target environment according to claim 1, characterized in that the block for matching the optical fluxes of radiation of the first and second ranges of the spectrum is made in the form of two pairs of flat mirrors installed in the course of the rays of the corresponding collimating lenses at an angle of 45 ° to their optical axes and perpendicular to each other, while the second along the beams mirrors in pairs are installed with the possibility of moving along the optical axis of the corresponding radiation flux in the areas between the mirrors in a pair.

Images