RU180291U1 - Device for monitoring the parameters of video systems - Google Patents

Abstract

The utility model can be used to measure the characteristics of optical systems, photo and television cameras, and thermal imaging systems. The device for monitoring the parameters of video systems contains temperature-calibrated emissivity sources of radiation, test objects in the form of a group of dashed worlds made up of mirror elements in the form of dihedral angles with different spatial frequencies, placed in the field of view of the controlled video system and means for processing the received signals. The edges of all dihedral angles that make up the worlds are parallel to each other. The device contains two radiation sources and they are optically connected to all worlds. The means for processing the received signals is made in the form of a computer equipped with appropriate software. The technical result is the acceleration of the certification process and increase reliability. 1 ill.

Description

The utility model relates to the field of instrumentation, namely, systems for measuring the characteristics of optoelectronic devices, and can be used to measure the characteristics of optical systems, photo and television cameras, thermal imaging systems.

A device for measuring the resolution limit of an information-measuring optoelectronic system based on imaging the dashed worlds, highlighting part of the dashed worlds and determining the resolution limit described in RU 2213335 [1]. The device for measuring the resolution limit is provided with a dashed world optically connected to an information-measuring optical-electronic system, for example, by means of a television camera lens, and a personal computer consisting of a system unit and a monitor. The luminous flux from a light source (not shown), passing through the dashed world or reflected from it, is converted into an electrical signal through the optical-electronic system under study, which is fed to the system unit. Moreover, the formation of the image of the dashed worlds, each element of which contains three groups of paired strokes with fill factors from minimum to maximum, is carried out on a computer screen. Observing the resulting image of the dashed worlds, visually determine the range of elements with fully resolved and completely unresolved stroke groups. Using software, select groups of strokes with the same fill factors located in different elements, and perform their low-frequency spatial filtering to reduce noise and, therefore, improve the accuracy of determining the magnitude of the brightness dips. A disadvantage of the known device is the inability to determine the sensitivity of the monitored device to radiation illuminating an object that is monitored using the device. In addition, the subjective factor affects the results, since resolution is determined visually.

A device for controlling the frequency-contrast characteristics of optical and optoelectronic observation devices containing a line of identical opaque elements is known. Moreover, each element of the device is made in the form of a prism with an equilateral triangle at the base, mounted on a common frame with the possibility of rotation about a vertical axis. The reflection coefficients of the neighboring faces of each prism are different, and the distance between the axes of rotation of the neighboring prisms is equal to the length of the side of the triangle at the base (SU 1478800 [2]). A disadvantage of the known device is the length of the process of determining the maximum resolution and the inability to determine the sensitivity of the monitored device to radiation illuminating an object that is monitored using the device.

Closest to the claimed in its technical essence is a device for measuring the parameters of optoelectronic devices, known from RU 2060487 [3]. The device contains temperature-controlled radiation sources calibrated by the black coefficient, test objects in the form of two dashed worlds made up of mirror elements in the form of dihedral angles with different spatial frequencies, placed in the field of view of the controlled video system. The first of the world is made as a periodic structure of bands that are the faces of a dihedral angle, and serves to measure resolution and can be performed with different spatial frequencies. The second world is the background and is also made of a set of dihedral angles, the edges of which are perpendicular to the edges of the first worlds, and the spatial frequency is insoluble for the controlled device. Four radiation sources are installed in the device, two of which are optically connected to one world, and the other two to the second. The disadvantages of the device are the duration of the procedure for measuring the parameters of the controlled device, because to determine the resolution it is necessary to sequentially set the worlds with different spatial frequencies. In addition, the main "means of processing the received information" is the operator, which must first "reliably detect the test object against a known background" and then "reliably detect the strokes of the test object", which significantly affects the reliability of the results.

The inventive device for monitoring the parameters of video systems is aimed at accelerating the certification process and increasing reliability.

This result is achieved by the fact that the device for monitoring the parameters of video systems contains temperature-calibrated emissivity sources of radiation with adjustable temperature, test objects in the form of a group of dashed worlds made up of mirror elements in the form of dihedral angles, with different spatial frequencies, placed in the field of view of the controlled video systems, and means of automatic processing of received signals. Moreover, the edges of all dihedral angles that make up the worlds are parallel to each other, the device contains two radiation sources and they are optically connected to all worlds, and the processing of the received signals is made in the form of a computer equipped with appropriate software. Distinctive features of the claimed device are:

- the edges of all dihedral angles that make up the worlds are parallel to each other and all of them serve to determine the resolution of the controlled device;

- the device contains two radiation sources and they are optically connected to all worlds;

- means for processing the received signals is made in the form of a computer equipped with appropriate software.

Using the world group to determine the resolution of a controlled device allows you to significantly speed up the determination of the resolution of a controlled device, since all dashed worlds are simultaneously located in the camera’s field of view, and the maximum resolution can be determined immediately from the results of the frame analysis. Setting all the world so that the edges of all the dihedral angles that make up the worlds are parallel to each other, allows them to be “seen” at the same time in the field of view of the controlled device and to ensure their optical contact with radiation sources, with only two sources being sufficient for successful operation.

Using a computer equipped with appropriate software as a means of processing the received signals allows, on the one hand, to significantly speed up the process of determining the parameters of the controlled device by processing one frame recorded in the computer's memory, and on the other hand, to eliminate the influence of a subjective factor in the face of the operator. In addition, this allows you to reduce the qualification requirements for personnel serving the proposed device.

The proposed device allows you to create a dashed world in a wide range of the optical spectrum, from ultraviolet to the mid-IR range, with the specified spatial distribution (step strokes), with a given and adjustable contrast in a wide range of average energy illumination.

Worlds of mirror elements with different slopes of the surface provide observation by a controlled video system of the emitting surface of two adjustable radiation sources.

The spectral range in which the device is used is determined by the parameters of the radiation source and is limited by the reflective properties of the mirror elements.

The design of the dashed worlds makes it possible to form the required geometric configuration from sections with different predetermined brightness, determined by the parameters of the radiation source to which individual mirror elements are oriented.

The high reflectivity of modern mirror coatings (over 0.97) will allow you to quantify the brightness of the elements of the object of observation and determine the sensitivity of the video system.

Creating a stroke world with a different spatial step of strokes will provide the ability to determine the angular resolution of video systems at different contrast values and different average brightness values of the object.

The essence of the claimed device is illustrated by an example implementation and a drawing, which shows a simplified image of the device. The device for monitoring the parameters of video systems contains a housing (not shown), calibrated by the black coefficient radiation sources 1 and 2 with adjustable temperature, test objects 3 in the form of a group of dashed worlds made up of mirror elements in the form of dihedral angles with different spatial frequencies, placed in the field of view of the monitored video system 4, and means 5 for processing the received signals in the form of a computer equipped with appropriate software. In this case, the edges of all dihedral angles that make up the worlds 4 are parallel to each other. The device is used as follows:

The monitored video system 4 is located against the dashed block world 3 so that the image of the dashed world is in the central field of view of the video system; The image of the world is focused by the controls of the lens of the video system.

In the computer software 5 all the data necessary for the calculations are entered:

- temperature or brightness of each radiation source;

- spatial frequencies of the dashed world;

- the distance from the monitored video system to the dashed block world;

- bandwidth of the video signal (determined by the frame rate).

The extended radiation sources 1 and 2 are arranged so that the video system “sees” the radiating surface of the source 2 through the “right” (conditionally) mirror faces and the radiating surface of the source 1 through the “left” faces.

At the operator’s command, registration is made of several (the number is set by the operator) consecutive frames of the image of the dashed block world in digital format.

The lens of the video system is closed by an opaque cover, and at the command of the operator, several “dark” frames are recorded in digital format (for noise calculation).

According to the registration of "dark" frames in digital format, the computer program calculates the noise of the video system using the Fourier transform or calculation of the standard deviation - at the choice of the operator.

According to the registration data of image frames of the image of a block of dashed world blocks in digital format, the program determines the amplitude of the signals from each world, dividing them by spatial frequency. The dependence of the amplitude on the spatial frequency - the frequency-contrast characteristic, is displayed on the monitor screen in tabular and / or graphical form.

Based on the amplitude of the signal from the dashed worlds with the lowest spatial frequency, the results of calculating the noise level of the video system and the data entered by the operator, the program calculates the threshold sensitivity of the video system.

The program makes calculations for all registered personnel; the average results are displayed on the monitor. This increases the accuracy of the measurement due to the multiplicity of the measurement process.

Claims (1)

A device for monitoring the parameters of video systems, containing temperature-calibrated black sources of radiation, test objects in the form of a group of dashed worlds made up of mirror elements in the form of dihedral angles with different spatial frequencies, placed in the field of view of the controlled video system and means for processing the received signals , characterized in that the edges of all dihedral angles that make up the worlds are parallel to each other, the device contains two radiation sources and they are optical and associated with all worlds, and received signal processing means comprises a computer provided with appropriate software.

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