RU2009522C1 - Laser unit for determining configuration of information light signal - Google Patents

Abstract

FIELD: laser engineering. SUBSTANCE: laser unit has light signal source 1, focusing optics unit 7 provided with drive, diaphragm 2 provided with drive, light flux divider 5, first scanner 3 provided with drive, first attenuator of light signal 4 provided with drive, light signals mating mirrors 13 and photodetector 14; all the units are connected in series and are conjugated optically. Unit also has movable mirror 6 provided with drive, first reflecting mirror 8, second scanner provided with drive, the second light signals attenuator 10 provided with drive, light filter 11 provided drive, the second reflecting mirror 12; all the units are connected in series and are optically conjugated. Device has amplitude limiting unit 15, videosignal amplitude numbering unit 16, videosignal duration numbering unit 17, coordinate processing unit 18, time processing unit 19, unit 20 for comparing measured values with standard values, synchronizer 21, information registrar 22 and unit 23 for controlling light signal radiation source 1 and amplitude and drives limiting unit. Movable mirror 6 provided with drive has input to be optically connected with the second output of light signal splitter 5. Output of the second reflecting mirror 12 is optically conjugated with the second input of light signals adjusting mirror 13. EFFECT: improved precision of determination. 2 dwg

Description

 The invention relates to laser technology, in particular to optoelectronic devices used to determine the configuration of the information light signal at different levels of relative power.

 A device for evaluating the characteristics of optical instruments is known, comprising a measurement source, a sensor, an alignment device with an electronic scan unit, a processing unit and a visualization unit.

 The disadvantage of this device is the inability to determine the configuration of the field of view of the radiation source at various levels of relative power.

 A laser device is known for determining the configuration of an information light signal, comprising an optically coupled light signal source, a focusing optics unit with a drive, a light divider, a first light attenuator with a drive and a photodetector, as well as a video signal amplitude digitization unit and an information recorder.

 The disadvantage of this device is the low accuracy of determining the configuration of the light signal at various levels of relative power.

 Achievable technical result is to increase the accuracy of determining the configuration of the information light signal at various levels of relative power.

 The specified technical result is achieved by the fact that the laser device for determining the configuration of the information light signal, comprising an optically coupled radiation source of the light signal, a focusing optics unit with a drive, a light divider, a first attenuator of a light signal with a drive and a photodetector, as well as a unit for digitizing the amplitudes of the video signal and the information recorder is equipped with a diaphragm with a drive, the first scanner with a drive, sequentially mounted and optically paired with a movable a glass with a drive, a first reflecting mirror, a second scanner with a drive, a second attenuator, a filter with a drive, a second reflecting mirror and a mirror for combining light signals, a block for limiting the amplitudes of the video signal, a series-connected unit for digitizing the duration of the video signal and a unit for comparing the measured values with the reference ones, as well as coordinate processing unit, temporary processing unit, serially connected by a synchronizer and a control unit, light signal emission source, unit limits of amplitudes and drives, while the diaphragm is optically coupled with the input to the output of the focusing optics unit and the output with the light flux divider, the first scanner is optically coupled with the input with the first output of the light divider and the output with the input of the first attenuator, which is optically coupled through the light mirror signals with a photodetector, a unit for comparing measured values with a reference is connected to the first output with the first input of the information recorder, the outputs of the unit for digitizing the amplitudes of the video signal, the unit for Ordinary processing, the temporary processing unit and the third output of the synchronizer are connected respectively to the second, third, fourth and fifth inputs of the measured value unit with the reference ones, which is connected to the second input of the control unit of the light signal emission source, the amplitude limiting unit and the drives connected by the first and the second outputs, respectively, with the input of the light source and the control input of the amplitude limiting unit, and the remaining outputs with inputs of the drives, synchronization the ator is connected by the second output to the second input of the information recorder, and the photodetector is connected by the output to the inputs of the amplitude limiting unit, the unit for digitizing the duration of the video signal, the coordinate processing unit, and the time processing unit.

 In FIG. 1 is a block diagram of a laser device for determining the configuration of an information light signal; in FIG. 2 is a block diagram of a control unit for a light source, an amplitude limiting unit, and drives.

 The laser device for determining the configuration of the information light signal comprises a light signal emission source 1, a diaphragm 2 with a drive, a first scanner 3 with a drive, a first attenuator 4 of a light signal with a drive, a light signal divider 5, a movable mirror 6 with a drive, a focusing optics unit 7 with drive, the first reflecting mirror 8, the second scanner 9 with the drive, the second attenuator 10 with the drive, the filter 11 with the drive, the second reflecting mirror, the mirror 13 combining light flux, the photodetector 14, block 15 restrictions amplitudes I, block 16 for digitizing the amplitudes of the video signal, block 17 for digitizing the duration of the video signal, block 18 for coordinate processing, block 19 for temporary processing, block 20 for comparing measured values with the reference ones, synchronizer 21, data logger 22, and block 23 for controlling the light signal emission source 1, block amplitude limits and drives. In this case, the light signal source 1, the focusing optics unit 7 with the drive, the diaphragm 2 with the drive, the light flux divider 5, the first scanner 3 with the drive, the light flux divider 5, the first scanner 3 with the drive, the first attenuator 4 of the light signal with the drive, a mirror 13 combining light signals and the photodetector 14 are arranged in series and optically paired. A movable mirror 6 with a drive, a first reflecting mirror 8, a second scanner 9 with a drive, a second attenuator 10 of light signals with a drive, a filter 11 with a drive and a second reflecting mirror 12 are arranged in series and are optically coupled. A movable mirror 6 with a drive is optically coupled to the input of the second output of the light divider 5, and the output of the second reflecting mirror 12 is optically coupled to the second input of the mirror 13 of the combination of light signals. The photodetector 14, the block 17 digitizing the duration of the video signal and the block 20 comparing the measured values with the reference are connected in series. The amplitude limiting block 15 is connected by an input to the output of the photodetector 19, and an output with the input of the block 16 of digitizing the amplitudes of the video signal. Block 20 comparing the measured values with the reference, is connected by the second, third, fourth and fifth inputs, respectively, with the outputs of the block 16 for digitizing the amplitudes of the video signal, the coordinate processing unit 18, the temporary processing unit 19 and the third output of the synchronizer, and the first and second outputs, respectively, with the first output of the recorder 22 information, which is connected to the second output of the synchronizer by the second input, the light source control unit 7, the amplitude limiting unit 15 and the drives are connected by the first and second inputs rows, respectively, to a first output and a second synchronizer output of comparator unit 20 the measured values with the reference, the first and second outputs, respectively, with the radiation source 1 input light signals and the control input of the amplitude limit unit 15, and other outputs from the drive input. The control unit 23 of the light signal emission source 1, the amplitude and drive limiting unit 15, comprises a long-term memory unit 24, a first read cell 25, a code signal comparison cell 26, an electronic chopper 27, a code signal addressing cell 28, a second read cell 29, an operational unit 30 memory.

 A laser device for determining the configuration of the information light signal operates as follows. Turn on a synchronizer 21, which generates synchronization pulses to a unit 20 for comparing the measured values with the reference ones, a unit 23 for controlling the light signal emission source 1, an amplitude limiting unit 15 and drives 15, and an information recorder 22. If there are clock pulses in the unit 20 for comparing the measured values with the reference ones, the equipment is preheated and information is read about the reference data by the length of the time interval between two video signals, the coordinate position of the center of the photodetector 14, the amplitude of the video signal, taking into account the relative level of the specified amplitude measurement interval. If there are clock pulses in the control unit 23 of the light source 1, the amplitude limiting unit 15 and the drives, the equipment is preheated and the information is read. If there is a control unit 23 in the above, the code signal enters the light emitting source 1 to turn on the latter. To set the angle of divergence of the light signal from this control unit 7, the code signals are sent to the drives of the focusing optics 7 and the diaphragm 2. In this case, the rough control loop is carried out using the drive of the diaphragm 2, and the exact one is controlled by the drive of the focusing optics 7. In addition, the code the control signal is supplied to the drive of the second attenuator 10 to set the maximum attenuation and to the drive of the first attenuator 4 to set the minimum attenuation. The light signal from the light signal radiation source 1, passing through the optical parts of the focusing optics 7 and the diaphragm 2, enters the divider 5, where it is divided into the first (main) and second (control) light signal. The control light signal passing the optical part of the movable mirror 6, is reflected from the first reflecting mirror 8 and passing the optical part of the second scanner 9 falls on the optical part of the second attenuator 10, where it is completely attenuated. The main light signal, having passed the optical parts of the first scanner 3 and the first attenuator 4, as well as the mirror for combining the light signals 13, is fed to a photodetector 14, where it is converted into a video signal. From the photodetector 14, through the block of limitation of amplitudes 15, the video signal is supplied to the block 16 of digitizing the amplitudes of the video signal. In addition, the video signal from the photodetector 14 is supplied to the block 17 for digitizing the duration of the video signal, the coordinate processing unit 18 and the time processing unit 19. In block 16 of the digitization of the amplitudes of the video signal determines the nominal value of the main video signal. The measurement results from block 16 digitizing the amplitudes of the video signal are sent to block 20 comparing the measured values with the reference. In the coordinate processing unit 18, the coordinate position of the main light signal in the field of view of the photodetector 14 is determined by the numbers of the illuminated channels of the photodetector 14. The measurement results from the coordinate processing unit 18 are sent to the unit 20 for comparing the measured values with the reference ones. In block 17, the digitization of the duration of the video signal determines the time interval between the leading and trailing edges of the video pulse. The measurement results from block 17 digitizing the duration of the video signal are sent to block 20 comparing the measured values with the reference. In block 19 time processing determines the time interval between two video pulses. In the absence of a control signal, the time interval between the two main signals is determined, that is, the radiation frequency of the main light signal is determined. The measurement results are sent to the unit 20 comparing the measured values with the reference, in which the obtained measurement results are compared with their reference values and the comparison results are sent to both the information logger 22 and the above control unit 23. In this block, based on the results obtained, control code signals are generated that are transmitted to the drives of the forming optics block 7, the diaphragm 2, the first scanner 3 and the first attenuator 4. Based on the results of digitizing the video signal using the diaphragm 2 and the focusing optics block 7, the cross-sectional size of the light signal. According to the results of coordinate processing using the first scanner 3, the light signal is combined with the center of the field of view of the photodetector 14. According to the results of digitizing the amplitudes of the video signal using the first attenuator 4, the necessary power of the main light signal is set. When the results of comparing the measured values with the reference, in addition to time intervals, are zero, that is, the calibration of the main signal is completed, then from the above control unit 23 to the drive of the first attenuator 4 a signal is issued to set the maximum attenuation of the main signal, and to the drive of the second attenuator signal for setting the minimum attenuation of the control signal. In this case, the main light signal will be absorbed by the optical part of the first attenuator, and it is possible to calibrate the control light signal.

 The control light signal from the light divider 5 enters the optical part of the movable mirror 6. Reflected from the movable mirror and the first reflective mirror 8 and passes through the optical parts of the second scanner 9, the second attenuator 10 and the filter, the control light signal, reflected from the second reflective mirror 12 and mirrors for combining light signals 13, is sent to the photodetector 14. The calibration process of the control video signal is similar to the calibration process of the main video signal. After calibrating the control video signal, the result of which is to set the duration of the video signal equal to the duration of the main video signal and the amplitude of the video signal limiting the lower measurement boundary, a control signal is generated in the above control unit 23 to reduce the maximum attenuation of the main light signal, i.e., the optical part of the first attenuator 4 is set to the passage of the main light signal in the desired power range. At the same time, control signals are generated in this control unit 23 to combine two light signals (main and control) in coordinates. These signals come from the above control unit 23 to the drives of the first and second scanners 3 and 9. For the simultaneous arrival of two signals to the mirror 13 for combining light signals in this control unit 23, a signal is generated that is transmitted to the drive of the movable mirror 6 to change the distance between its reflecting mirrors. In the same control unit 23, a control signal is generated that is transmitted to the drive of the second attenuator 10 to limit the upper limit of the light signal power measurements. After that, in this control unit 23, a control signal for changing the spectrum of the control light signal is supplied to the drive of the filter 11. To limit the lower limit of the measurement range of the video signal power to the amplitude limiting block 15, a code signal is received from the above control block 23 corresponding to a predetermined lower limit value. Thus, a video signal characterizing only a certain interval of the radiation power of the main light signal is supplied to the block 17 for digitizing the duration of the video signal and to the block 18 for coordinate processing. The totality of the measurement results of the amplitudes of the video signal and its coordinate position characterizes its shape. To determine the cross-sectional shape of the light signal when measuring the measuring range in the above control unit 7, control signals are generated that are sent to the second attenuator 10 and to the amplitude limiting unit 15 to change the amplitude characteristics of the lower and upper boundaries of the light signal power measurements. The process of determining the configuration of the light signal has the steps of calibrating the main light signal, calibrating the control light signal, combining the main and control light signals, forming a measurement range and determining the cross-sectional configuration of the combined light signal simulating an information light signal. It should be noted that the upper boundary of the measurements is formed by combining two light signals with different spectral characteristics. As a result, the light signal is absorbed in a given range of radiation power. The lower limit of the measurement range is formed by changing the magnitude of the limitation of the amplitudes of the combined video signal. The shape of the cross section of the light signal is determined by the location of the illumination channels of the photodetector 14 with a minimum amplitude of the video signal. The accuracy of determining the cross-sectional shape of the light signal depends on the size of the illumination channel and on the discrete digitization of the amplitude. (56) French Patent N 2151262, cl. G 01 M 11/00, 1974.

 Volkenstein, Kuvaldin. Photoelectric pulse photometry, Mechanical Engineering, 1975, p. 89, fig. 48.

Claims (1)

 A LASER DEVICE FOR DETERMINING THE CONFIGURATION OF THE INFORMATION LIGHT SIGNAL, comprising optically coupled light source, a focusing optics unit with a drive, a light divider, a first light attenuator with a drive and a photodetector, as well as a unit for digitizing the amplitudes of the video signal and the information recorder, which it is equipped with a diaphragm with a drive, a first scanner with a drive, sequentially mounted and optically paired with a movable mirror with a drive, the first from a reflection mirror, a second scanner with a drive, a second attenuator, a filter with a drive, a second reflecting mirror and a mirror for combining light signals, connected in series by a unit for digitizing the duration of the video signal and a unit for comparing the measured values with the reference ones, as well as a coordinate processing unit, a time processing unit connected in series a synchronizer and a control unit for the light source of the light signal, a block for limiting the amplitudes of the video signal and drives, while the diaphragm with the input is optically coupled by the input to the output of the focusing optics unit, and the output is connected to the light flux divider, the first scanner is optically coupled by the input to the first output of the light divider, and the output is connected to the input of the first attenuator, which is optically coupled through the mirror combining light signals with the photodetector comparing the measured values with the reference connected to the first output with the first input of the information logger, the outputs of the unit for digitizing the amplitude of the video signal, the coordinate processing unit, the time processing unit the current and the third output of the synchronizer are connected respectively to the second, third, fourth and fifth inputs of the unit for comparing the measured values with the reference ones, which is connected to the second input of the control unit of the light signal radiation source connected to the first and second outputs, respectively, with the input of the light signal radiation source and the control input of the amplitude limiting unit, and the rest of the outputs with the inputs of the drives, the synchronizer is connected by the second output to the second input of the information recorder, and photodetector the receiver is connected by an output to the inputs of the block for limiting the amplitudes of the video signal, the block for digitizing the duration of the video signal, the block for coordinate processing, and the block for temporary processing.

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