RU2240635C1 - Intracavity-controlled radiation laser - Google Patents

Abstract

FIELD: laser engineering; data transfer and processing systems, laser location, and other industries.

SUBSTANCE: laser has cavity accommodating active element, polarizer, and radiation control device incorporating modulator and its control circuits. Modulator uses heat-correction circuit arrangement set up on two chips, electrical connection between these chips being open; first and second control circuits are connected to first and second chips, respectively. First control circuit is optically coupled with laser cavity and can rapidly change control voltage within characteristic time lower than that taken by beam to traverse over laser cavity τ _c ; second control circuit is optically coupled with laser cavity and ensures control voltage response time longer than or equal to τ _c .

EFFECT: minimized control voltage for long-time generation of ultrashort pulse length comparable with time of laser using phototropic saturable absorber.

6 cl, 7 dwg

Description

The invention relates to laser technology, in particular to devices for generating stable ultrashort, mainly picosecond, light pulses, and can be used in information transmission and processing systems, laser location, material processing.

A known laser with intracavity radiation control, in particular stabilization of parameters using negative feedback, in which the intracavity control device is based on a Kerr liquid cell (H. Statz et al. “Problem of Spike Elimination in Lasers”, Journal of Applied Physics, vol. 36, No.5, 1965, p.1510), for the control of which it is necessary to form a voltage of several kV.

The use of the transverse electro-optical effect in crystals allows reducing the control voltage in the negative feedback system to hundreds of volts when creating an intracavity radiation control device. The closest to the claimed combination of essential features is a picosecond laser with an intracavity negative feedback system based on the ML-102 modulator and an intracavity saturable absorber described by A.I. Andreev et al. “YAG: Nd laser in passive mode synchronization mode with negative feedback based on a high-current photomultiplier ”, Quantum Electronics, t.16, No. 8, 1989, p.1604. A saturable absorber synchronizes the laser modes, and negative feedback allows one to obtain quasistationary generation, during which picosecond pulses are generated. However, the limited photostability of a saturable absorber leads to a gradual change in the parameters of the generated pulses. In addition, in the described device, the delay in the positive feedback circuit is fundamentally excluded, which impedes the implementation of generation modes with a wide stability region. The instability manifests itself in the fact that with an increase in the pump during the time course of the laser radiation, self-pulsations occur, followed by a transition to a chaotic mode of operation, in which the radiation power is a random function of time.

The present invention solves the problem of creating a laser with intracavity radiation control at the lowest possible control voltage for the long-term generation of ultrashort pulses of a duration comparable to the duration of a laser pulse using a phototropic saturable absorber.

The problem is solved in that in a laser with intracavity radiation control containing an active element, a polarizer and a radiation control device containing an electro-optical modulator located in the resonator, said modulator is made according to a thermally compensated circuit of at least two crystals, while the electrical connection between the crystals is open, and the first and second control circuits are associated with the first and second crystals, respectively, while the first control circuit is configured to quickly change neniya control voltage with a time less than the time of traversal τ radiation laser resonator _p, and the second control circuit is optically coupled to the laser resonator and provides a response time of a control voltage greater than or equal to τ _p.

The radiation control device is located near the dead mirror of the laser and is based on a thermally compensated electro-optical modulator, consisting of two or more crystals with a transverse electro-optical effect, while the electrical connection between the crystals is open, and each crystal has its own control circuit, and the second control circuit is connected with a crystal located farther from the dead mirror and is optically coupled to the resonator, and the first is connected to a crystal located closer to the mirror.

The voltage gain in the inventive laser is provided by the use of a transverse electro-optical effect in a thermally compensated modulator. The modulator is made, for example, in the form of two specifically oriented crystals (Mustel ER, Parygin VN “Methods of modulation and scanning of light”, M .: Nauka, 1970, p. 33, Fig. 11.11). In the traditional use of the modulator, both crystals are electrically connected. In the inventive laser, the electrical connection between the crystals is open and the crystals are used independently, but the thermal compensation is not disturbed. In the inventive laser, the second section of the modulator (second crystal) is used to implement negative feedback, ensuring the stabilization of its radiation. The first section serves to form an ultrashort laser pulse and shorten its duration. Moreover, a more rapid change in voltage leads to the generation of light pulses of shorter duration.

The first control circuit can be made in the form of a harmonic oscillation generator with a generation frequency N / τ _p , where N is an integer. The minimum oscillation frequency is 1 / τ _p . Under certain conditions, the control circuit of the second crystal allows the mode to self-synchronize due to fast delayed negative feedback and generate pulses of duration τ that are single on the axial interval (DB Vorchik, MV Gorbunkov. Self-synchronization of Nd-YAG laser modes in fast mode delayed negative feedback using high-voltage assemblies of reverse biased silicon pn junctions. Physical processes in devices of electronic laser technology. Proceedings of MIPT, M., 1995, p.4). In this case, the frequency of the control voltage of the first section can be increased to ν _m ≈ 1 / τ, and ν _m must be a harmonic of the frequency 1 / τ _p to synchronize the effects of the first control circuit with the moments of the passage of the light pulse through the modulator.

The first control circuit can also be made in the form of a high-quality shock excitation circuit at a frequency N / τ _p , where N is an integer. The circuit contains a photodetector optically coupled to the optical delay line, which in turn is optically coupled to the laser cavity, wherein the oscillations in the circuit are excited by photodetector current pulses.

The first modulator control circuit can also be made in the form of a generator of a sequence of ultrashort electrical pulses with a repetition rate that is a multiple of 1 / τ _p .

The first control circuit can also be made in the form of a relaxer containing a photodetector optically coupled to the laser cavity through a delay line. Relaxator performance is determined by two parameters: the photocurrent response time τ _f and the relaxation time RC _m , where C _m is the modulator crystal capacitance and R is the resistance through which the C _m discharge occurs. Optimal control is achieved when RС _m does not exceed τ _f . To generate pulses of shorter duration, it is desirable to choose photodetectors with a minimum τ _f .

In order to ensure generation of single pulses on the axial interval of a sufficiently short duration in the mode of self-synchronization of modes with a quick negative feedback shifted in time, a sufficiently sharp time course of losses is necessary. Therefore, the second control scheme should also be performed based on the relaxer. The optimum value of _m in the second RC section control circuit is 1-3 τ _p.

The invention is illustrated by the description and drawings.

Fig. 1 shows a laser circuit with intracavity radiation control, Fig. 2 shows a laser circuit in which the first control circuit is optically coupled to the laser cavity through a delay line, Fig. 3 is a diagram of a shock excitation circuit comprising a photodetector, and Fig. 4 is a control circuit in the form of a relaxer containing a photodetector; FIG. 5 is a transmission time path of an intracavity modulator controlled by a circuit based on a relaxer performing negative feedback; FIG. 6 is a transmission time course of a two-section Fig. 7 shows the time course of transmission of a two-section intracavity modulator with the first and second control circuits based on a relaxer.

The laser consists of an active element 1 located in a cavity formed by mirrors 2 and 3. A polarizer 4 and a radiation control device including a two-section thermocompensated modulator based on a transverse electro-optical effect are also placed in the cavity, the first 5 and second 6 sections of which are made in a certain way oriented crystals, the electrical connection between which is absent. The first section of the modulator 5 is located as close as possible to the deaf mirror 2. The control circuit 7 is electrically connected to the first section of the modulator, and the control circuit 8 with its photodetector 9 is electrically connected to the second section of the modulator. The first control circuit is capable of quickly changing the control voltage with a characteristic time shorter than the time taken by the radiation of the laser cavity τ _p . The second control circuit is optically coupled to the delay line 10 and provides a response time of the control voltage greater than or equal to τ _p . The first control circuit 5 can be made in the form of a harmonic oscillation generator with a generation frequency that is a multiple of N / τ _p , where N is an integer (item 2), as well as an ultrashort electric pulse generator (item 4). It can also be made in the form of a high-quality shock excitation circuit at a frequency N / τ _p (item 3), including a photodetector 11, optically connected to the resonator through an additional delay line 12 or a pulse generator based on the relaxer (item 5), also containing a photodetector 11, optically coupled to the resonator via an additional delay line 12. The second control circuit 8 can be made in the form of a relaxer (item 6) containing a photodetector 9.

A laser with intracavity radiation control operates as follows. Part of the laser radiation is removed from the resonator formed by the mirrors 2 and 3 (Fig. 1), and through the delay line 10 it passes to the photodetector 9 of the second control circuit 8. The delay is selected so that the light pulse passes through the modulator at the moment of the maximum opening of the second section 6 .At the same moment, the voltage rapidly changing in time is supplied to the first section of the modulator 5, providing for a short time even greater opening of the modulator, which provides an additional sharpening of the time course of the transmission modulator .

The negative feedback circuit formed by elements 6, 8, 9, and 10 makes it possible to stabilize the parameters of laser radiation, enter the quasi-stationary generation mode, and provide sufficient time for the formation of ultrashort pulses.

A rapid change in losses near the moment of passage of the light pulse through the modulator provided by the first section leads to the formation of an ultrashort light pulse. The duration of the steady-state pulse, taking into account the changed time course of the transmission modulator is determined as follows:

where T _max - the maximum transmission modulator

- величина второй производной пропускания T(t) по времени в момент достижения максимального значения Т_max,

- the value of the second derivative of the transmission T (t) with respect to time at the time of reaching the maximum value of T _max ,

Δ f is the width of the gain line of the active medium of the laser,

g ₀ is the saturated gain at the center frequency of the gain line when the light bypasses the resonator completely.

The modulator sections can be controlled using harmonic signals (laser according to claim 2 and claim 3) or periodic voltage pulses (laser according to claim 4, claim 5 and claim 6). The control signal can be constant in amplitude (active mode synchronization) (laser according to claim 2 and claim 4) or depend on the intensity of laser radiation (laser according to claim 3, claim 5 and claim 6). In the latter case, external positive or negative feedback is realized.

When applying harmonic control voltage, it is advisable to use a high modulation frequency. For a resonator with a round-trip time, resonant frequencies that are multiples of 1 / τ _p are acceptable. In order to ensure generation of single pulses on the axial interval, in the case of using high harmonics, a sufficiently sharp time course of losses caused by the action of negative feedback is necessary. Therefore, to build a negative feedback system, it is advisable to use a relaxer circuit.

The principle of negative feedback in this case is as follows. Part of the radiation is removed from the laser cavity and, with a certain delay, is fed to the photodetector of the control circuit. The increase in radiation power corresponds to an increase in intracavity losses, which leads to stabilization of radiation, that is, external negative feedback is realized. In the case of the generation of ultrashort pulses with an optimal control signal delay, the following time course of intracavity losses takes place (Fig. 5).

The charge of the capacitance by the photodetector current corresponds to a sharp increase in losses. A slow decrease in losses with a characteristic relaxation time corresponds to a discharge of the gate capacitance. The severity of the time dependence T (t) is determined by the response time of the photodetector and the time constant of the charge of the capacitance. The use of fast photodetectors with a response time much shorter than τ _p makes it possible to efficiently use higher harmonics of frequency 1 / τ _p to control the second section of the modulator.

The application of short voltage pulses to the first section of the modulator makes it possible to use a less pronounced time modulation of losses caused by the action of negative feedback. For the relaxer, this allows the use of large values of RC _m and thus increase the sensitivity of negative feedback. The characteristic time course of intracavity losses at optimally selected control delays in the first and second sections is shown in Fig.7.

The optimal delay in controlling the second section is the same as in the case of the relaxer, in the first one so that a short control pulse arrives at the moment of minimal losses due to the action of the second section of the modulator.

The inventive device allows for intracavity radiation control, including stabilization of its parameters, mode synchronization, etc. The device can be used in information transmission and processing systems, laser location, and other industries.

Claims (6)

1. A laser with intracavity radiation control, comprising an active element, a polarizer and a radiation control device located in the resonator, the radiation control device comprising an electro-optical modulator, characterized in that said modulator is made according to a temperature-compensated circuit of at least two crystals, while the connection between the crystals is open, and the first and second control circuits are connected to the first and second crystals, respectively, the first control circuit being It is capable of rapidly changing the control voltage with a characteristic time shorter than the time of the laser radiation rounding τ _r , and the second control circuit is optically coupled to the laser resonator and provides a control voltage response time greater than or equal to τ _p . 2. The laser according to claim 1, characterized in that the first control circuit is made in the form of a harmonic oscillation generator with a generation frequency N / τ _p , where N is an integer. 3. The laser according to claim 1, characterized in that the first control circuit is made in the form of a high-quality shock excitation circuit at a frequency N / τ _p containing a photodetector optically coupled to the laser resonator via a delay line. 4. The laser according to claim 1, characterized in that the first modulator control circuit is made in the form of an ultrashort electric pulse generator. 5. The laser according to claim 1, characterized in that the first control circuit is made in the form of a relaxer containing a photodetector optically coupled to the laser cavity through a delay line. 6. The laser according to claim 1, characterized in that the second control circuit is made in the form of a relaxer containing a photodetector optically coupled to the laser cavity through a delay line.

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