RU2593918C1 - Device for measuring energy of powerful nano- and picosecond transmission-type laser pulses - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to measurement equipment and device for measuring energy of powerful laser radiation pulses. Device includes a laser radiation source, a diffusing medium, an optic-fiber collector, an attenuator of laser radiation, a photodiode, measuring and computing unit. Diffusing medium used is a diffusing diffuser made as a cylindrical washer from diffusing glass. Diffuser is installed into a flange located at minor angle to the optical axis of the laser beam. On external surface of washer branched ends fiberoptic collector are fixed uniformly in circumferential direction with possibility to adjust distance to surface of diffuser. Collector provides optical signal transmission through attenuator to photodiode. Outlet of collector is secured with possibility to adjust distance to attenuator.

EFFECT: technical result is the improvement of accuracy and wider range of power density of the measured radiation.

3 cl, 1 dwg

Description

The invention relates to the field of measuring equipment and technical physics, in particular to the creation of devices for measuring the energy of powerful pulses of laser radiation.

The prior art devices for measuring the energy of high-power laser pulses using pyroelectric primary measuring transducers manufactured by Ophir Optronics Solutions Ltd [1]. Devices of the type PE50-DIF-ER-C and PE100BF-DIF-C make it possible to measure the energy of a pulsed laser beam with an energy of up to 40 J with a pulse duration of 0.002 ms to 20 ms with a repetition rate of up to 25 Hz to 10 kHz. Moreover, the power density of the measured laser radiation in one pulse with a beam diameter of ≈33 mm is ≈2.5-10 ⁶ W / cm ² , which is typical for pulses of the micro- and millisecond duration range.

However, to solve the problems of measuring the energy of high-power laser pulses in the nano- and picosecond ranges of durations, the aforementioned devices are not adapted to high power densities ≈ (1-5) · 10 ⁹ W / cm ² due to the low value of the limiting optical power density of pyroelectric receivers, the excess of which leads to their damage or to an irreversible change in metrological characteristics. In addition, these devices are not devices of the type through passage and thus do not allow simultaneous energy measurements and the use of a laser beam for further use.

The problem of expanding the range of durations of high-power laser pulses when measuring energy and using a laser beam for further use can be effectively solved by using pass-through devices based on measuring only a small part of the scattered radiation, and ensuring that the bulk of the radiation passes through an optically transparent scatterer without significant attenuation .

The closest analogue of the proposed device is a device operating on the basis of a non-contact method for measuring the power of laser radiation, based on measuring the scattering of the secondary glow from aerosol particles from refractory material when exposed to laser radiation with an intensity of more than 10 ³ W / cm ² [2]. The error in measuring the laser characteristics of the proposed method is determined by the accuracy of measuring the concentration of luminous particles. This concentration, in turn, can be measured with high accuracy if the aerosol stream is formed as a flat layer. However, the creation of a wide homogeneous high-speed aerosol layer is a rather complicated technical task, as the authors mention directly in the document [2], and the possible solution to this problem does not consider the metrological aspect, which is essential when creating both new measurement methods and the corresponding device methods.

The technical problem solved by the claimed invention is to create a high-precision device for measuring the energy of high-power nano- and picosecond laser pulses of a continuous type with a power density of ≈ (1-5) · 10 ⁹ W / cm ² , in which the measurement result does not depend on the type of spatial intensity distribution of the laser beam.

The technical result achieved by the implementation of the claimed invention consists in increasing the range of power density when measuring the energy of laser pulses, increasing the accuracy of measuring energy regardless of the type of spatial distribution of the intensity of the laser beam with the ability to use the laser beam for further use, as well as simplifying the design of the device for measuring the energy of laser pulses.

The specified technical result is achieved due to the fact that the device contains an optical element made in the form of a cylindrical washer made of optical glass, located at a small angle to the optical axis of the laser beam to eliminate the effect of backward radiation reflected from the washer. Thus, the main part of the radiation passes without significant attenuation, and the scattered radiation enters the fiber optic collector, matched by the level of the optical signal with a photodiode, at the input of which a neutral attenuator is installed with the possibility of adjusting the distance of the position of the end of the fiber optic collector supplying scattered radiation from the cylindrical washer to the surface attenuator, which allows you to change the intensity of the radiation entering the photodiode, since the intensity changes back roportsionalno square of said distance, and the branched ends of the optical fibers collector, which receives the scattered radiation from a lateral surface of the washer, are arranged to adjust the distance from them to the external cylindrical surface of the washer, which allows alignment of the band characteristics of the device, i.e., to ensure that the intensity of the radiation incident on the branched ends of the fiber optic collector depends only slightly on the position of the laser beam entering the device relative to the cylindrical washer, which ultimately leads to an increase in the accuracy of energy measurement. The composition of the claimed device for measuring energy includes a measuring and computing unit containing an integrating device that performs the function of converting the current pulse from the output of the photodiode to a voltage pulse, the amplitude of which is proportional to the radiation energy at the input of the photodiode, a voltage amplifier with a variable gain determined by the value of the laser energy radiation to create the necessary level of electric signal for the peak detector to work, peak detector for storing and storing information about the value of the peak amplitude of the pulse, an analog-to-digital converter for converting the electrical signals of the peak detector to digital information, a microprocessor in which, using specially developed software, by software approximation of the conversion characteristics of the photodiode by the least squares method, the non-linearity of the mentioned characteristic is reduced to level 0, 5-0.7% in the range of two to three decimal orders of energy change, an indicator for visualizing the result s measurements.

Regardless of the type of spatial distribution of the intensity of the laser beam entering the cylindrical washer, the distribution structure at its output due to scattering is smoothed out and approaches uniform, which ensures the required accuracy of energy measurement regardless of the type of the initial spatial intensity distribution.

The fiber optic collector provides the transmission of the optical signal from the cylindrical washer due to scattering to the photodiode, which reduces the effect of electromagnetic interference during the pulse due to the structural removal of the photodiode from the direct laser radiation path, which increases the accuracy of energy measurement.

The described design of the optical circuit of the device provides the required attenuation of the laser beam energy to the level necessary for measuring it with a photodiode. The ability to adjust with screws the distance from the outer cylindrical surface of the washer to the branched ends of the fiber optic collector can reduce the influence of the band characteristics of the device on the result of energy measurement, which increases the accuracy of energy measurement.

The presence of a neutral attenuator at the input of the photodiode and the ability to adjust with a screw the distance from the end of the fiber optic collector opposite to the branched ends to the surface of the attenuator allows you to match the level of the selected scattered radiation with the linearity range of the photodiode, which also improves the accuracy of energy measurement.

A diagram of the inventive device for measuring laser pulse energy in a preferred embodiment is shown in FIG. 1. The device is a measuring transducer 1, an optically transparent diffuser of passage type 2, made in the form of a cylindrical washer made of optical glass, for example, grade K-8, mounted in a flange located at a small angle to the optical axis of the laser beam to prevent back reflection on laser, and on the outer cylindrical surface of the diffuser 3 branched ends of the fiber optic collector opposite to the horse are mounted and fixed by screws 3 which is fixed to the frame with a screw 5, where a neutral radiation attenuator 6 and a photodiode 7 are placed coaxially with the end 4, a measuring and computing unit 14 containing an integrating device 8, an amplifier 9, a peak detector 10, an analog-to-digital converter (ADC) 11, microprocessor 12 and indicator 13. The microprocessor provides software approximation of the characteristics of the photodiode by the least squares method using specially designed software.

The device operates as follows. The laser radiation enters the scatterer 2. The main part of the radiation flux passes through the scatterer without significant attenuation, and the scattered radiation from its lateral surface enters the branched ends of the fiber optic collector 4, then to the neutral attenuator 6 and to the photodiode 7. The pulsed laser arriving at the photodiode 7 radiation is converted into a current pulse. The photodiode current pulse is supplied to an integrating device 8, converting it into a voltage pulse, the amplitude of which is proportional to the radiation energy at the input of the photodiode. The voltage pulse from the output of the integrating device through the amplifier 9 is fed to the input of the peak detector 10, which "remembers" and "stores" information about the value of the peak amplitude of this pulse for the time (~ 100 μs) necessary for its measurement and registration.

Thanks to this, the device allows the measurement of energy, both a single pulse and a sequence of laser pulses with a repetition rate of up to 10 ³ -10 ⁴ Hz.

From the output of the peak detector, the signal goes to the ADC 11, where it is converted to digital information, the digitized signal from which goes to the microprocessor 12. The microprocessor reads the data into the internal memory for subsequent processing and generation of signals for visualization on the indicator 13.

Literature

[1] Website www.ophiropt.com/laser-measurement. Catalog of power and energy meters "OPHIR".

[2] N.N. Belov, A.A. Negin. Copyright certificate SU No. 701221, cl. IPC: G01J 1/58, 1986.

Claims (3)

1. A device for measuring the energy of high-power nano- and picosecond laser pulses of a through type, containing a laser source, attenuator, scattering medium, a propagation channel of scattered laser radiation, a measuring and computing unit, characterized in that the scattering medium is formed by an optically transparent diffuser of a through type, made in the form of a cylindrical washer made of optical glass mounted in a flange located at a slight angle to the optical axis of the laser beam, and on the outer the cylinder surfaces are evenly circumferentially mounted and fixed by means of screws with the possibility of adjusting the distance to the cylinder surface to align the zone characteristics of the device with the branched ends of the fiber optic collector, which ensures the transmission of the scattered part of the optical radiation through the attenuator to the photodiode, the opposite to the branched ends of the fiber optic collector being fixed to the frame with screw, allowing by adjusting the distance from it to the surface of the attenuator with zdaval desired signal transmitted by fiber-optic attenuator to the collector, used to align the optical circuit with the characteristic of the photodiode, wherein the transmission-type lens provides radiation to pass therethrough without substantial attenuation. 2. The device according to p. 1, characterized in that the optically transparent diffuser is made in the form of a cylindrical washer made of glass brand K-8. 3. The device according to p. 1, characterized in that the measuring and computing unit contains a microprocessor in which the software approximates the conversion characteristics of the photodiode by the least squares method using special software.

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