SU1141300A1 - Lens quality control device - Google Patents

Abstract

1. DEVICE FOR MONITORING QUALITY OF LENSES, containing illuminators sequentially installed on the same optical axis, a test object installed in the focal plane of the collimator, a micro-lens whose objective plane is displaced with the image plane of the monitored lens, an analyzer, a recorder, characterized in that increase the accuracy of control and reduce its time, the test object is a fixed grid with discretely varying spatial frequencies minutes, the analyzer is set to the image plane and the microlens vtolnen a linear samoskanirukitsego instrument receiving pad which is arranged perpendicular strokes mec: tobekta, podklyuchennogok inputted generator 3 O takto- synchronized power pulse, and an output linear) Nogo samoskaniruyuschego device connected to the recorder.

Description

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2, The device according to claim 1, wherein the linear self-skipping device is implemented as a device with charge transfer.

3. The device according to claim 1, characterized in that the recorder is made in the form of a video processor, control unit, counter, processing unit, information output unit, and the analyzer is connected to the first input of the video processor and the second output of the control unit, the input of which is connected to the generator synchronized power clock, and the first output is connected to the second input of the processing unit and the reset input of the counter, the third output of the control unit is connected to the second input of the video processor, the output of which is connected to the first input m processing unit, the second output of which is connected to the main input of the counter, and a first output connected to the first input of the output information, a second input coupled to an output of the counter.

A1300

4. The device according to claim 3, wherein the processing unit consists of a peak detector, two trigger storage sampling schemes, a comparison circuit and an extremum detector, the first output of which is connected to the reset input of the peak detector, and the second output is connected to the second output of the processing unit and the first trigger input, the second input of which is connected to the second input of the processing unit, and the output to the control input of the first sample-storage scheme, the main input of which is connected to the output of the peak detector and the first input of the comparison circuit, the second the course of which is connected to the output of the first sampling-storage scheme, and the output is connected to the main input of the second sampling-storage scheme, the control input of which is connected to the third output of the extremum detector, and the output is connected to the first output of the processing unit, and the input of the extremum detector and the information input of the peak detector connected to the first chadom processing unit.

The invention relates to measurement instrumentation, and serves for the operative control of the quality of lenses by determining the modulation transfer function during their alignment and certification and can be used in optical-economic factories for automated quality control of lenses.

A device for controlling the quality of lenses is known, comprising an illuminator, a test object in the form of a slit diaphragm, an auxiliary lens, a control lens, a raster with discretely varying in frequency dashed grids, which are placed on mismatched raster tracks. The raster rotates in front of the photodetector, which is connected to narrowband electric filters.

The disadvantages of this device are the small number of recorded points on the FPM curve, which limits its scope, low reliability associated with the presence of moving parts, for example

rotating raster, several selective amplifiers, complex electronic processing circuitry.

It is also known a device for controlling the quality of lenses containing an illuminator, a collimator, a micro lens, the subject of which | is aligned with the image plane of the monitored lens, an analyzer, a photoelectronic receiver, an amplifier and a recording device E2l.

The disadvantages of the known device are a long time and low control accuracy associated with the need to move both the grid and the analyzer.

The purpose of the invention is to improve the accuracy of control and reduce its time.

 This goal is achieved by the fact that in a device for controlling the quality of lenses containing successively installed Others on the same optical axis illuminators, a test object installed in the focal plane of the collimator, a micro-lens whose object plane is aligned with the image plane of the monitored lens, an analyzer, a recorder, a test -object is a fixed-mounted grating with a discrete-varying spatial frequency, the analyzer is installed in the image plane of a micro-lens configured as a linear samoskaniruyuschego device receiving area which are arranged perpendicular to the strokes of the test object is connected to input clock generator synchronized power pulse, and the output of the linear samoskaniruyuschego device connected to the recorder.

In this case, the linear self-scanning device is implemented as a linear device with charge transfer.

Moreover, the recorder is made in the form of a video processor, a control unit, a counter, a processing unit, an information output unit, while the analyzer is connected to the first input. video processor and the second output of the control unit, the input of which is connected to the generator of synchronized power clock, and the first output is connected to the second input of the processing unit and the reset input of the counter, the third control output connected to the second input of the video processor, the output of which is connected to the first input of the processing unit, The second output of which is connected to the main input of the counter, and the first output is connected to the first input of the information output unit, the second input of which is connected to the output of the counter

In addition, the processing unit consists of a peak detector, two storage sampling circuits, a trigger, a comparison circuit and an extremum detector, the first output of which is connected to the reset input of the peak detector, and the second output is connected to the second output of the processing unit and the first trigger input, the second whose input is connected to the second input of the processing unit, and the output to the control input of the first sampling-storage scheme, the main input of which is connected to the output of the peak detector and the first input of the comparison circuit, the second input of which is connected to the output the house of the first sample storage circuit, and the output is connected to the main input of the second sample storage circuit, the control input of which is connected to the third output of the extremum detector, and the output is connected to the first output of the processing unit, the input of the extremum detector and the information input of the peak detector input processing unit.

FIG. Figure 1 shows the device, optical layout; in fig. 2 the same, structurally-electrically. scheme.

A device for monitoring the quality of lenses contains a collimator located along the beam, including a radiation source 1, a capacitor 2 and a test object 4 installed at the focus of the collimator lens 3 with a discretely changing spatial frequency, a controlled lens 5 is installed coaxially with the collimator, with a plane-image of which the object plane of microobtection 6 is combined.

In the image plane of the latter, an analyzer 7, embodied as a self-scanning linear chain of photosensitive elements as a linear device with charge transfer 8, is installed, the receiving areas of the linear device with charge transfer oriented perpendicular to the strokes of the test object 4, and the recorder 9.

The device also contains an electronic part consisting of a control unit 10, a power clock generator 11, a processing unit 12, a counter 13, a video processor 14, an information output unit 15. The processing unit 12 comprises a detector 16. extremum, peak detector 17 trigger 18, two sampling-storage circuits 19 and 20, comparison circuit 21.

The output of the video processor 14 is connected to the first input 22 of the processing unit 12, the first input is connected to the photo-receiving unit 7, and the second input

connected to the third output of the control unit TO. The first output of the control unit 10 is connected to the second input 23 of the processing unit 12 and the reset input of the meter 13, the second output is connected to the photoreceiver unit 7, and the input under the switch is connected to the generator 11 of clock pulses. The output of the counter 13 and the first output 24 of the processing unit 12 is connected to the inputs of the information output unit 15. The input of the extremum detector 16 is connected to the information input 12. The first output of the extremum detector 16 is connected to the reset input of the peak detector 17, the second output to the first input of the trigger 18 and the second output 25 of the processing unit 12. The output of the peak detector 1.7 is connected to the main input of the first sampling-storage circuit 19 and the first input of the matching circuit 21, the second input of which is connected to the output of the first sampling-storage circuit 19, the control input of which is connected to the output of the trigger 18; to the main input of the second sampling-storage circuit 20, the control input of which is connected to the third output of the extremum detector 16, the output of the sampling-storage circuit 20 is connected to the first output 24 of block 12, the second input of the trigger 18 is connected to the second input 23 of block 12, the second the output 25 of which is connected to the main input of the counter 13.

The purpose of the main units of the device is as follows.

The photodetector unit 7 serves to convert optical information into a time sequence of electrical pulses with an amplitude proportional to the average level of illumination on the corresponding photosensitive elements of the linear chain. The control unit 10 generates control signals necessary for organizing a specific video signal processing algorithm from the photodetector unit 7, Video processor 14 produces amplification and double correlated video signal sampling, which allows receiving a signal free from correlated interference due to the presence of a linear device reset mode with charge transfer and penetrating the video signal due to capacitive coupling between the electrodes. Block 12 about 006

according to a predetermined algorithm, the video signals are analyzed and the output of the received information is output to the block 15. Counter 13 is designed to encode a discrete sequence of spatial frequencies present in test object 4.

The device works as follows.

When a controlled lens 5 is installed in the seat, the image of the test object 4, illuminated with the help of light source 1 and condenser 2, is projected by a collimator lens 3 and controlled by lens 5 into the object plane of microobject 6, - which; with magnification, it projects the image of test object 4 onto the analyzer 7, whose receiving-element as a device with charge transfer, 8 converts the image sent to it into a temporal sequence of electric unipolar pulses, the envelope of which is adequate to the spatial distribution of illumination along the photosensitive ruler. A charge transfer device records, on command from the generator, 11 synchronized clock pulses. The signals received from the device with charge transfer are fed to the input 9 of the oscilloscope, on the screen of which one observes U (t) corresponding to the sought distribution of illuminance E (x) in the image of test object 4 on the photosensitive ruler. The nature of the illumination distribution in the image of the test object depends on the change in its spatial frequency. At the same time bending | with respect to the level of 0.5E (where E is the maximum illumination at zero spatial frequency) is the transfer function of the modulation of the monitored lens.

When using an electronic processing unit, the device operates as follows.

Illuminated by a light source 1 (FIG. 1) and a capacitor 2, test object 4 is designed by collimator 3 and controlled by 5 lenses into the subject plane of the micro-lens. The latter forms, on a linear chain of photosensitive elements of the analyzer 7, an enlarged image of the test object 4. The analyzer 7, for example, based on a linear device with charge transfer, converts optical information into a temporal sequence of electric unipolar pulses, the envelope of which is adequate to the spatial distribution of illuminance images on a linear transfer device p (yes) (LPPZ). The control of the LRTP scanning process and the synchronization of the operation of the whole circuit is carried out by the control unit 10, which is connected to the generator 11 power supply pulses. The video signal from the output of the analyzer 7 is fed to the first input of the video processor 14. which performs the transformation and amplification of the signal, thus increasing the signal-to-noise ratio and eliminating interference caused by the passage and overlapping of the useful signal of the clock and reset pulses, s using a double correlated sample. The generated video signal from the output of the video processor 14 enters through the first input 22 of the processing unit 12 to the information input of the peak detector 17 and to the input of the extremum detector 16. Peak detector 17 captures the value of the gear ratio1 | modulation at the h-th spatial frequency, and the extpeViywa detector 16 detects the instant of the n-th spatial frequency by the instant of the occurrence of the positive extremum of the video signal. When the video signal of the first maximum appears (corresponds to zero spatial frequency), the peak detector 17 captures the value of this maximum, and the extremum detector 16 determines the moment of arrival of the amplitude maximum of zero spatial frequency. After that, from its second output to the main input of the counter 13 and to the first input of the trigger 18, an impulse arrives to record the amplitude level of the zero spatial frequency and, When this pulse arrives at the trigger 18, it goes into one of the stable states, with this signal from the trigger 18 to the control input of the first sample storage circuit 19, translates it into the storage mode of the maximum signal amplitude level at zero spatial frequency —m--, which is subsequently used as a reference voltage and supplies c to the second input of the comparison circuit 21, to the first input of which comes from the peak detector 17, the amplitude value of the signal level at zero spatial frequency, equal to After the comparison, the difference signal 1 ---) goes to the main (UMC, KC-input of the second sampling-storage scheme 20 and at the moment when the recording pulse control arrives at its input from the extremum detector 16, this difference signal is recorded in the memory element of the sample-storage circuit 19. At the same time, the recording pulse removed from the third output of the extremum detector 16 has a short time hydrochloric delay relative to the pulse, removes from its second output. The magnitude of the time delay is determined by the speed of the comparison circuit 21. Through the first output 24 of the processing unit 12, the fixed value of the difference signal characterizing the relative value of the PMC at zero spatial frequency is fed to the first input of the information output unit 15, the second input of which comes from the counter 13, which determines the discrete spatial frequency. 4, zero spatial frequency code. After the differential signal has been written to the memory element of the second sampling-storage circuit 20, the first output of the extremum detector t6 inputs a reset input to the peak detector 17 to reset the peak detector 17. When the video processor 14 arrives at the first input 22 of the processing unit 12, the positive extremum value video signal at the next spatial frequency, the peak detector 17 captures this value (it corresponds to the maximum value of the PMC at a given spatial frequency. Trigger 18 does not change its value with standing, and the reference input UMMKCO continuously arrives at the second input of the comparison circuit 21

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positive extremum of a signal proportional to the QPM at a given spatial frequency, received at the first input of the comparison circuit 21 Difference sig ,, ™ rm / UlMXXXUMC4KC

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at the moment of pulse arrival at the control input from the third output of the extremum detector 16 is recorded in its memory element and through the first output 24 of the processing unit 12 enters the information output block 15. Thus, a sequential measurement of the PMC of the lens at other spatial frequencies, as well as the determination of the number of the spatial frequency corresponding to the given PMR, is performed. The aggregate of all QPM controlled lens for various spatial frequencies possessed by the test object is the MTF of the controlled lens.

The proposed device for monitoring the transmission function of the lens modulation, as compared to the known ones, allows monitoring the quality of the lens at all working spatial frequencies with higher reliability in a smaller span of time and with better quality.

Claims (4)

1. DEVICE FOR CONTROL OF QUALITY OF LENSES, containing illuminators sequentially mounted on the same optical axis, a test — an object installed in the focal plane of a collimator, a micro-lens, the subject plane of which is mixed with the image plane of the controlled lens, an analyzer, a recorder, characterized in that - that, in order to increase the accuracy of control and reduce the time it takes, the test object is a fixed array with a discrete spatial frequency, and alizator installed in the image plane and the microlens is formed as a linear samoskanirukitsego instrument receiving pad which is arranged perpendicular strokes testobekta, podklyuchennogo'k inputted clock generator synchronized power pulse, and the output of the linear samoskaniruyuschego device connected to the recorder. and.,. 1141300 FIG. 1 2. The device pop. 1, the fact that the linear self-scaling device is made in the form of a device with charge transfer. 3. The device according to p. 1, characterized in that the recorder is made in the form of a video processor, control unit, counter, processing unit, information output unit, while the analyzer is connected to the first input of the video processor and the second output of the control unit, the input of which is connected to generator synchronized clock power pulses, and the first output is connected to the second input of the processing unit and the reset input of the counter, and the third output of the control unit is connected to the second input of the video processor, the output of which is connected to the first input a processing unit, the second output of which is connected to the main input of the counter, and the first output is connected to the first input of the information output unit, the second input of which is connected to the output of the counter. 4. The device pop. 3, characterized in that the processing unit consists of a peak detector, two trigger storage sampling circuits, a comparison circuit and an extremum detector, the first output of which is connected to the reset input of the peak detector, and the second output is connected to the second output of the processing unit and the first trigger input, the second whose input is connected to the second input of the processing unit, and the output is to the control input of the first sampling-storage circuit, the main input of which is connected to the output of the peak detector and the first input of the comparison circuit, the second input of which is connected to the output of the first sample-storage circuit, and the output is connected to the main input of the second sample-storage circuit, the control input of which is connected to the third output of the extremum detector, and the output is connected to the first output of the processing unit, the input of the extremum detector and the information input of the peak detector are connected to the first child processing unit.