RU93777U1 - DEVICE FOR MEASURING THE INCORPORTIVITY OF THE HELICOPTER BLADES OF A HELICOPTER - Google Patents

Abstract

 1. A device for measuring the inconsistency of the rotor blades of a helicopter containing an optical head including a lens and a photodetector optically coupled to it, a video signal processing unit comprising a comparator and an interframe difference shaper, and an information output unit, characterized in that the optical head is made sequentially an analog-to-digital converter connected to the photodetector, and the video signal processing unit comprises a former of the averaged image frame, and an amplitude detector, a block for selecting the coordinates of the tips of the blades, a block for averaging the coordinates of the tips of the blades, an imager for recognizing the blades and a recognition unit for the first blade, while the output of the imager of the averaged image frame is connected to the input of the imager of the interframe difference, the second input of which is connected to the output of the analog-to-digital converter, and the output of the imaging difference interframe is connected to the input of the amplitude detector, one of the inputs of the comparator and to the input of the imaging device of the blades, the output of the amplitude detector is connected to the second input of the comparator, the output of the comparator is connected to the input of the block for selecting the coordinates of the tips of the blades, the output of which is connected to one of the inputs of the unit for averaging the coordinates of the tips of the blades, and one of the inputs of the imager of the image of the blades, the second input of the imager of the image of the blades is connected to the output of the shaper interframe difference, the output of the block averaging the coordinates of the tips of the blades is connected to one of the inputs of the recognition unit of the first blade, the second input of which

Description

The invention relates to optical-electronic measuring equipment, and in particular to devices for measuring the coordinates of fast moving objects, and can be used to measure the inconsistency of the rotor blades of a helicopter.

A device is known for measuring the coordinates of fast-moving objects (see V.I. Zamyatin, "Optoelectronic devices based on solid-state photodetectors", Barnaul, 1991, p.10). The device comprises an optical radiation source, a light flux modulator, and an optical head including a lens, an optically coupled photodetector connected in series with a voltage scanner and an amplifier, and a video signal processing unit including units for automatic gain control, digital information processing, selection and allocation of coordinates, indications and information output, sequentially interconnected. As a modulator of the light flux, optical radiation sources are used, mounted on the tips of the rotor blades and made, for example, flashing. The installation of optical radiation sources at the tips of the rotor blades introduces design changes and may imbalance the latter, which can lead to the separation of the blades and, as a result, to the death of the helicopter and crew. Due to the use of a photodiode array as a photodetector, the device has a high speed and greater noise immunity, however, in real conditions, the radiation of clouds, topographic details of the relief of the earth's surface, inhomogeneous radiation of the atmosphere, reflected or scattered radiation of various sources create a total radiation field described only by a random function of the energy luminosity. Therefore, when determining the coordinates of the tips of the rotor rotor blades against a constantly changing radiating background, for example, with variable cloud cover, numerous false positives occur, caused by the formation of temporary gates in the areas of the difference in the energy brightness of the sky background.

Closest to the claimed solution, taken as a prototype is a device for measuring the coordinates of the blades of a rotor rotor of a helicopter, described in patent No. 2180122, priority 2000.05.06, patent holder, Andrey Mikhailovich Kuznetsov. The device comprises an optical radiation source, a light flux modulator and an optical head including a lens, an optically coupled photodetector connected in series with an amplifier, and a video signal processing unit including units for automatic gain control, digital information processing, selection and coordinate allocation, indication and output information sequentially interconnected. The device is equipped with a subtractor, and the digital information processing unit is made in the form of an analog-to-digital converter, a storage device and a digital-to-analog converter, one of the outputs of the display and information output unit is connected to the second input of the storage device, the output of the digital-to-analog converter is connected to one of the inputs a subtractor, the second input of which is connected to the output of the automatic gain control unit, and the output of the said subtractor is connected to the input m block selection and processing of the video signal, in addition, the device is equipped with a sensor of the first blade, the output of which is connected to one of the inputs of the display device and information output.

The presence of the first blade sensor allows you to accurately identify each rotor blade, but it should be noted that the first blade sensor must be mechanically mounted on the outside of the helicopter, while the helicopter design, namely such elements as an additional fuel tank or helicopter fuselage features, can make it difficult to install . Installing the sensor of the first blade outside reduces the safety, since there is a danger of the sensor coming off and falling into the rotor of the helicopter, which can lead to an accident.

Another disadvantage of the known device is the use of analog circuitry for the selection and processing of the video signal, which requires preliminary tuning of the analog processing nodes and makes the circuit dependent on the amplitude of the input video signal, which affects the accuracy of the measurements. In addition, the device does not contain nodes for storing information obtained during the measurement process, which suggests the presence of additional equipment to document it, or the constant duty of an operator who will record manually. The device uses the well-known principle of calculating the interframe difference to distinguish moving objects from stationary ones. Since the sky is inactive with respect to rapidly rotating blades, the amplitude modulation caused by the sky is almost eliminated in the video signal at the output of the subtractor. The method of obtaining an image frame that does not contain a blade signal relies on the use of a signal from the sensor of the first blade, since it involves synchronization with the azimuthal position of the blades.

The signal is formed to compensate for the background by storing the signal of the frame received between the blades, which requires a separately generated synchronization signal with the azimuthal position of the blades using additional equipment, which uses a separate synchronization circuit with a separate optical sensor.

In addition, in this solution, to measure the inconsistency of the blades, it is necessary to maintain a stable amplitude of modulation of the light flux in the measurement channel.

The objective of the claimed solution is to increase the accuracy and reliability of measuring the inconsistency of the rotor blades of the helicopter, as well as improving ease of use and simplifying the design of the device for measurement.

This goal is achieved due to the fact that in the known device for measuring the inconsistency of the rotor blades of a helicopter containing an optical head, including a lens and an optically coupled photodetector, a video signal processing unit containing a comparator and interframe difference generator, and an information output unit, an optical head is made comprising an analog-to-digital converter connected in series with a photodetector, and the video processing unit comprises a driver l the average image frame, the amplitude detector, the block for selecting the coordinates of the tips of the blades, the block for averaging the coordinates of the tips of the blades, the imaging unit for the blades and the recognition unit for the first blade, while the output of the imaging unit for the average image frame is connected to the input of the imager of the interframe difference, the second input of which is connected to the output of the analog -digital converter, and the output of the interframe difference shaper is connected to the input of the amplitude detector, one of the inputs of the comparator and to the input of the image finisher of the blades, the output of the amplitude detector is connected to the second input of the comparator, the output of the comparator is connected to the input of the block for selecting the coordinates of the tips of the blades, the output of which is connected to one of the inputs of the unit for averaging the coordinates of the tips of the blades, and one of the inputs of the imager of the image of the blades, the second input of the imager of the image of the blades connected to the output of the shaper of the interframe difference, the output of the block averaging the coordinates of the tips of the blades is connected to one of the inputs of the recognition unit per the second blade, the second input of which is connected to the output of the blade imager, the output of the recognition unit of the first blade is connected to one of the inputs of the information storage unit and one of the inputs of the display unit, the second input of the information storage unit and the display unit is connected to the output of the averaging unit of the blade tip coordinates, the third input of the information storage unit and the display unit is connected to the output of the blade imager.

And also due to the fact that the photodetector is made in the form of a single-line CCD, the optical head contains an automatic brightness control signal shaper whose output is connected to the lens, and the video signal processing unit contains a time interval measuring unit, the input of which is connected to the output of the comparator, and the output with the input of the unit for averaging the coordinates of the tips of the blades, with the input of the recognition unit of the first blade and with the inputs of the information storage unit and the indication unit; the information output unit includes an information storage unit and an indication unit.

The technical result obtained by the implementation of the proposed invention is that the formation of the reference video signal to compensate for the background is averaged over the entire signal for a certain previous time interval, comparable to the time of rotation of the screw. Since the sum of the widths of the blades is less than 5% of the perimeter of the rotor of the helicopter, in the average signal of the frame collected over a time comparable to the rotation of the rotor, the distortion of the background due to the signals from the blades falling into the total amount will not exceed 5% of the increment of the amplitude of the current video signal, caused by the blade. This distortion will remain in the difference signal after subtracting the reference video signal from the current one, but it does not affect the result, since, for example, a 50% level of the maximum amplitude obtained from the difference signal for some previous time, also comparable to the screw rotation time. The determination of the first rotor blade is carried out by selecting the corresponding signal during image processing, and not by using additional equipment.

The claimed device uses a fully digital channel without analog processing elements, which allows the use of modern highly integrated digital microcircuits and the entire processing channel can be placed in a minimum number of microcircuit cases, which reduces the dimensions and weight of the device, improves reliability, reduces power consumption, and incorporates it into one device the ability to switch settings to different types of rotorcraft with a different number of blades, in addition, each digital processing channel Vai pixel photodetector has a physical address that enables calibration after measuring the distance between the blades wingtips amount photodetector elements separating trajectories image endings blades. Thus, the digital channel allows you to save the geometric reference of objects to the numbers of the CCD elements in which they were found and, accordingly, the accuracy of measuring the relative position of objects is determined by the distance between the objects transmitted by two adjacent CCD elements.

The digital stream can also be directly recorded on the storage medium, and thus receive a complete video recording of events, the processing of which is carried out separately from the test mode.

The claimed solution does not require constant maintenance of the maximum and stable amplitude of the light flux modulation in the measurement channel, since all signal processing occurs in digital form, thus, there are no signal processing elements that can be adjusted to specific amplitudes of the signal and thereby increase the dynamic range, allowing work in a wide range of illumination. The claimed combination of features is unknown to the applicant from available sources of information, on the basis of which it can be concluded that the claimed solution is new. An analysis of the known solutions shows that the claimed solution allows the process of measuring the inconsistency of the rotor blades of a helicopter not previously used device. The claimed solution is illustrated by drawings, where:

Figure 1 presents a block diagram of a device;

Figure 2 presents a frame image of the sky between the blades;

Figure 3 presents the image frame of the blade against the sky;

Figure 4 presents the average image frame;

Figure 5 presents the differential frame of the image;

The block diagram of the device includes an optical head 16, a signal processing unit 17 and a node for storing and displaying information 18.

The optical head 16 includes a lens with a controlled aperture 1, a photodetector (FPU) 2 in the form of a single-line CCD, an analog-to-digital converter (ADC) 3, and an automatic brightness control signal shaper (ARY) 4.

The signal processing unit 17 comprises a shaper of the averaged image frame 5, a shaper of inter-frame difference 6, an amplitude detector 7, a comparator 8, a block for selecting the coordinates of the tips of the blades 9, a block for averaging coordinates of the tips of the blades 11, a unit for measuring time intervals 10, a shaper of images of the blades 12 and a recognition unit first blade 13.

The node for storing and displaying information 18 consists of an information storage unit 14 and an indication unit 15.

Before starting measurements, the base blade is marked and the necessary parameters of the tested helicopter are set (the number of blades, the distance from the lens to the tip of the blade, etc.)

The sky image periodically blocked by the blades passes through the lens 1 to the photodetector (FPU) 2. It is a single-line device with a charge-coupled device (CCD) with the number of photosensitive elements in line 2048, so the image frame formed by the CCD is one line with a length of 2048 elements. The CCD is oriented in the image focusing plane so that when the blade intersects the optical axis of the lens, the CCD line should be deployed from the tip of the blade to the axis of the rotor and capture the image area behind the tip of the blade and part of the blade. The rate of generation of image frames is such that during the passage of the next blade the CCD will form several image frames in which the signal of the blade will be present. The analog signal with the FPU is digitized element by element using a 10-bit ADC 3 and fed to the inter-frame difference shaper 6 and the averaged image frame shaper 5, which produces an averaged image frame, summing up successive frames over a time comparable to the screw revolution time. From the output of the last video signal, the averaged frame is fed to the inter-frame difference shaper 6 and to the automatic brightness control (ARA) signal shaper 4. The ARY signal shaper controls the lens aperture, maintaining the CCD illumination to the extent that its light-signal characteristic can be considered linear, then without Distortions are transmitted by halftones of the image and the contours of objects on a bright background, and it is possible to carry out without limitation arithmetic operations of summing and subtracting over the signal. The inter-frame difference shaper 6 subtracts the frame averaged over the previous screw rotation from the current frame and generates a video signal that does not contain a background component in the image area free of blades. This signal falls on the amplitude detector 7. The detector in the passing digital stream of frames captures the maximum amplitude of the signal caused by the passage of the blade, and stores the obtained value. The current video signal of the inter-frame difference is compared by the comparator 8 with a predefined value proportional to the detector output signal (maximum signal amplitude for the previous period), for example, 50% of the maximum signal amplitude for the previous period. If the comparator is triggered, the current difference frame is considered to contain the image of the blade, in addition, the pixel number of the image by which the comparator worked is remembered as the coordinate of the tip of the blade by the block for selecting the coordinates of the tips of the blades 9. Of the consecutive frames in which the comparator worked, the block for selecting the coordinates of the tips the blades 9 determines the minimum coordinate of the tip of the blade, which is considered to be the desired one. To increase the reliability of measurements in the conditions of vibration of the aircraft, leading to an error in measuring the coordinates of the tips of the blades, maneuvering and wind, causing the blades to sway, an averaging unit for the coordinates of the tips of the blades 11 is used, in which the coordinate of the tips of each blade is averaged over a given number of rotor rotations. The time interval measuring unit 10 fixes the frequency of occurrence of a series of frames with a sign of the presence of a blade signal, averages it and calculates the actual rotor speed, in addition, it predicts the time limits for the next blade to fly in front of the lens, taking into account the inertia of the rotor and in case of violation, for example , due to the direction of the FPU against the sun or the exit of the tip of the blade beyond the edge of the display area, it develops a sign of failure of the synchronization of the blades, causing a restart of the averaging procedure eniya blades coordinates. The imaging device of the blades 12 contains a memory array divided into segments, the number of which corresponds to the number of rotor blades of the helicopter, and the number of lines in the segments is obviously larger than single-line frames onto which one flying blade is projected at the slowest operating rotor speed. The current video signal of the interframe difference from the output of the shaper 6 is stored in the lines of the current memory segment, for consecutive frames in which the comparator worked, then the next memory segment is selected and the recording is repeated under the same conditions and so on, until all segments are filled. Thus, only blades containing an image are selected from the total frame stream, which dramatically reduces the amount of information needed for further processing. The result is a two-dimensional array, in which there are 2048 elements per row, and in columns the number of rows in a segment multiplied by the number of segments. The recognition unit of the first blade 13 receives a picture of the blades from the shaper 12, and the address of the beginning of the blade in each segment from the block 11 and runs the search algorithm for a colored spot on one of the blades. After finding the spot, the blades are numbered from the painted base. The information storage unit 14 allows you to save at arbitrary points in time the measured values of the relative position of the trajectories of the tips of the blades, the speed of the rotor, as well as video recordings of fragments or constantly the behavior of the tips of the blades in different test modes with subsequent playback of the recording. The display unit 15 visually displays the relative position of the tips of the blades in a vertical plane, the relative displacement of the trajectories of the tips in millimeters, the numbering of the blades, the rotational speed of the rotor and other parameters. Technically, the blocks 13, 14 and 15 are made in the form of a laptop with appropriate software.

During the tests, the position of the blades is displayed on the computer screen of the signal processing unit in real time and the inconsistency is measured in all modes. To increase the reliability of measurements, a television image of the blades is displayed on the visual indication in addition to the inconsistency values, which allows you to visually assess the correct operation of the measuring circuit of the device. The computer of the processing unit is equipped with software for analyzing the received information about the tests and making recommendations for adjustment. All information obtained during the tests is stored in a computer database and can be used for further processing. The equipment is easily reconfigurable for various types of helicopters having different lengths and widths of the blades and their number.

Claims (5)

1. A device for measuring the inconsistency of the rotor blades of a helicopter containing an optical head including a lens and a photodetector optically coupled to it, a video signal processing unit comprising a comparator and an interframe difference shaper, and an information output unit, characterized in that the optical head is made sequentially an analog-to-digital converter connected to the photodetector, and the video signal processing unit comprises a former of the averaged image frame, and an amplitude detector, a block for selecting the coordinates of the tips of the blades, a block for averaging the coordinates of the tips of the blades, an imager for recognizing the blades and a recognition unit for the first blade, while the output of the imager of the averaged image frame is connected to the input of the imager of the interframe difference, the second input of which is connected to the output of the analog-to-digital converter, and the output of the imaging difference interframe is connected to the input of the amplitude detector, one of the inputs of the comparator and to the input of the imaging device of the blades, the output of the amplitude detector is connected to the second input of the comparator, the output of the comparator is connected to the input of the block for selecting the coordinates of the tips of the blades, the output of which is connected to one of the inputs of the unit for averaging the coordinates of the tips of the blades, and one of the inputs of the imager of the image of the blades, the second input of the imager of the image of the blades is connected to the output of the shaper interframe difference, the output of the block averaging the coordinates of the tips of the blades is connected to one of the inputs of the recognition unit of the first blade, the second input of which it is single with the output of the image sensor of the blades, the output of the recognition unit of the first blade is connected to one of the inputs of the information storage unit and one of the inputs of the display unit, the second input of the information storage unit and the display unit is connected to the output of the averaging unit of the blade tips, the third input of the information storage unit and the display unit is connected to the output of the image sensor blades. 2. A device for measuring the inconsistency of the rotor blades of a helicopter according to claim 1, characterized in that the photodetector is made in the form of a single-line CCD. 3. The device for measuring the inconsistency of the rotor blades of a helicopter according to claim 1, characterized in that the optical head contains a driver of a signal for automatically adjusting brightness, the output of which is connected to the lens. 4. The device for measuring the inconsistency of the rotor blades of a helicopter according to claim 1, characterized in that the video signal processing unit includes a time interval measuring unit, the input of which is connected to the output of the comparator, and the output - with the input of the unit for averaging the coordinates of the tips of the blades, with the input of the recognition unit the first blade and with the inputs of the information storage unit and the display unit. 5. A device for measuring the inconsistency of the rotor blades of a helicopter according to claim 1, characterized in that the information output unit comprises an information storage unit and an indication unit.