LT5168B - Generator of short light pulses - Google Patents

Abstract

The present invention relates in general to the field of quantum electronics, and in particular to lasers with tunable pulse duration, employing the stimulated backwards scatterings technique. It can be used in the development of laser locators, inmaterial research, various technological applications etc. The generator of short light pulses consists of the following optically coupled components arranged along a single optical axis: a total reflection mirror, quality modulator, the first polarizer, active medium with pumping means, pinhole and output mirror behind which a phase-retarding element, objective and Brillouin-active medium are placed. The novelty of invention lies in the act that the generator is equipped with polarization control unit, fast photodetector and electrical pulse generator electrically coupled with the pumping scheme. The control inputs of this polarization control unit are electrically coupled with corresponding outputs of pulse generator and fast photodetector, while the ph

Description

The invention relates to the field of quantum electronics, namely, pulsed-adjustable lasers using forced light backscattering, and can be applied to the development of laser locators, materials science, various technologies, and the like.

There is a swinging laser that emits pulses of adjustable ripple light, which has an optical pulse laser, a rotating mirror, a polarizer, a Pokels cage and a fully reflecting mirror arranged in one optical axis and optically coupled, as well as a polarization rotating unit an electrode unit having electrically coupled photodiode, a high-speed comparator, an emitter repeater, an adjustable delay line and electrically associated therewith two high-frequency keys connected to said Pokels cage electrodes. The pulse duration in the generator is varied by varying the delay between high-torque key opening moments (U.S. Patent No. 4483005, H01S 3 / 10,1984).

The closest to the present invention is a laser with pulse compression laser having a fully reflective mirror arranged in one optical axis and optically coupled, a quality modulator, a polarizer, an active medium with a storage device, an output reflector with a phase-shifting element, a positive focal lens, assembled from two positive lenses, one fixed and the other mounted, and filled with Brillouin active medium cuvettes. (USSR Invention No. 1795851 H01S 3 / 00,1992) Disadvantages of a known laser include:

- there is no possibility to accurately synchronize the laser pulse with an external event;

- high storage energy;

-A change in impulse energy at the output is possible only by changing the laser optical elements or by introducing additional losses, i.e. degrading laser efficiency;

- high depolarization background;

- unstable output pulse characteristics.

The object of the invention is to increase the accuracy of the generated short pulses synchronization with an external event, i.e. to obtain the optimum pulse passage in time with respect to the electric 'synchro pulse', while achieving maximum laser efficiency and parametric stability.

The essence of the problem is that a short-light pulse generator having a fully reflective mirror, a quality modulator, a first polarizer, an active medium with an accumulator, an aperture and an output mirror with a phase-shifting element, arranged in one optical axis and optically coupled and a Brillouin active medium, further comprising a polarization control unit, a high-speed photo receiver and an electrical pulse generator, electrically coupled to the storage device, said quality modulator being controlled by a signal from a polarization control unit whose control inputs are respectively electrically coupled to the pulse generator the outputs, wherein the input of said photoelectric is optically coupled to the first polarizer, furthermore, a first quarter-wave wafer is positioned in the optical axis behind the first polarizer before the active medium, and this medium contains a second quarter-wave plate, a spectrum narrowing element placed in front of the exit mirror, a second polarizer positioned behind the exit mirror's optical axis, and the lens is a variable or fixed focal point.

The control of the quality modulator on the optical axis from the synchronization pulse from the oscillator increases the accuracy of the synchronization of the generated short light pulses with an external event, i.e. allows for the passage of time over the optical pulse with respect to the electrical synchronization pulse. The additional control of the light generated by the signal from the high-speed photo receiver, along with the spectrum narrowing element and the two phase plates, ensures smooth light pulse generation while achieving maximum laser efficiency and parameter stability during Brillouin scattering.

The controlled quality modulator consists of first and second electro-optical crystals disposed on the optical axis between the fully reflecting mirror and the first polarizer, and the polarization control unit consists of two separate polarization control units, the output of the first polarization control unit electrically coupled to the first , while the output of the second polarization control unit is electrically coupled to the second electro-optical crystal, and the inputs respectively to a pulse generator and a high-speed photo camera whose input is optically coupled to said first polarizer.

In this way, in addition to the usual quality control of an electro-optical resonator, the function of which is the first electro-optical crystal with a polarization control unit, the quality control of the resonator in proportion to the amount of light hitting the high-speed photo receiver. This control is performed by a second electro-optic crystal and a second polarization control unit that maintains low light energy in the resonator for a longer period of time than a conventional resonator and, when complexed with a spectrum narrowing element and a pair of quarter-wavelength phase plates. When the first electro-optical crystal and polarization control unit are turned on, the weak single-frequency contamination is amplified and the pulse with a smooth envelope is emitted. This pulse is sent to Brillouin's active medium and compressed in time.

The controlled quality modulator consists of one multi-electrode electro-optical crystal controlled from a single polarization control unit, the first input electrically coupled to the pulse generator output directly and the second input electrically coupled to the pulse generator via an additional polarization control unit and directly to a high speed photoelectric input coupled to the first polarizer.

This technical solution simplifies the construction of the generator.

The spectrum narrowing element is placed in the thermostat. This ensures long-term laser stability.

The spectrum narrowing element and the output mirror comprise a single output mirror having spectrum narrowing properties. This simplifies the construction of the laser.

The invention is further explained in the drawings, wherein:

FIG. 1 is a general schematic diagram of the proposed laser;

FIG. Fig. 2 is a schematic of Fig. 1 of the proposed schematic of a laser; FIG. Fig. 3 is a schematic of Fig. 2 of the proposed schematic diagram of a laser; FIG. 4 is a diagram of the laser (Fig. 2);

FIG. 5 is a working diagram of the laser (Fig. 3).

The short-pulse laser consists of a fully reflecting mirror 1, aligned in one optical axis and optically coupled, controlled modulator 2, polarizer 3, aperture 4, quarter-wavelength phase plate 5, active medium 6 with storage device 7, quarter-wavelength phase plate 8, spectra a tapering element 9, an output mirror 10, further downstream of the polarizer 11, a quarter-wavelength phase plate 12, a positive variable focal lens 13, a cuvette with Brillouin active medium 14. The polarizer 3 is optically coupled to the inlet of the high-speed photo receiver 15. coupled to the first input of the polarization control unit 16. The second input of the polarization control unit 16 is coupled to the output of the pulse generator 17, the other output of which is coupled to the storage device 7 (excitation element).

FIG. The short-pulse laser-controlled quality modulator 2 of Fig. 2 consists of two electro-optical crystals 18 and 19 disposed on the optical axis between the fully reflecting mirror 1 and the polarizer 3, and the polarization control unit comprises two polarization control units 20 and 21, respectively. 20 is electrically coupled to the control input of the electro-optical crystal 18, and the other output of generator 17 via the polarization control unit 21 is coupled to the control input of the electro-optical crystal 19. The other input of the polarization control unit 21 is electrically coupled to the output of the fast photo receiver 15.

FIG. The short-pulse laser-controlled quality modulator 2 of Fig. 3 consists of a multi-electrode electro-optical crystal 22 disposed in the optical axis between the fully reflecting mirror 1 and the polarizer 3, controlled by a single polarization control unit 23 having one input electrically coupled to a corresponding output of generator 17 coupled to the output of the high-speed photo receiver 15 and via the additional polarization control unit 24 to the other output of the generator 17.

The short-pulse laser operates as follows. At the time point ti (Fig. 4), the accumulator 7 starts accumulating the active medium 6. At the same time point tj, a voltage Ui is applied to the electrodes 18 of the first electro-optical crystal 18 (Fig. 4), and the resonator quality is reduced to such an extent that generation begins only with maximum inversion of the active medium 6 (time moment t _2> Fig. 4). At the onset of generation, a portion of the light reflected from the polarizer 3 enters the fast photo receiver 15, which, through the polarization control unit 21, transmits a voltage proportional to the generation to the second electro-optical crystal 19, resulting in increased resonator losses. . During the amplification of the active medium 6 and the losses controlled by the photoelectric device, the resonator generates a constant generation level (diagram E, t ₂ -t _{3) (} Fig. 4). With such a generation and operation of the spectral selector 9, it is possible to generate only one eigenfrequency of the resonator. At time t _{3, the} voltages U ₁ , U _{2 are} removed from the first and second electro-optical crystals 18 and 19 (Ulir U2, Fig. 4). Losses in the resonator are reduced to zero and a powerful single-frequency pulse with a smooth envelope develops. After exiting the resonator, this powerful pulse passes the polarizer 11, the quarter-wavelength phase plate 12, and the lens 13 is focused on the Brillouin active medium 14. After a forced Brillouin scatter, the shortened pulse bounces back through the lens 13, the quarter-wavelength plate. , which reverses polarization and is reflected from polarizer 11. Since all generation and control processes are synchronized with generator 17, the laser pulse output from the polarizer is precisely synchronized with the synchronous pulse t ₃ (diagram "Gen", Fig.4).

The short pulse generator is shown in Fig. 3, in which a controlled quality modulator functions by a single multi-electrode electro-optical crystal 22 controlled by a single polarization control unit 23. An additional polarization control unit 24 is provided to maintain a constant generation development time t ₂ -t ₃ (Fig. 4). , provides long-term stability. The working time diagram of this generator is shown in Fig.5. At the time instant ti, the accumulator 7 begins to accumulate the active medium 6. The current Iil flowing through the impulse lamp of the accumulator is shown in the top diagram of Fig. 5. At the same time, voltage U (Fig. 5) is applied to the electro-optic crystal 22, which reduces the resonator quality to such an extent that generation begins only at maximum inversion in the active medium 6 (time moment t ₂ in Fig. E, Fig. 5). The start of generation of reflected from the polarizer 3 part of the light enters the ^one-speed photodetector 15, which in the polarization control unit 23 to the electro-optic crystal 22 transmits the voltage U that is controlled in proportion to the time t ₂ -t _third As time increases t ₂ -t _{3, the} voltage is increased and shortened - decreased (AU in diagram U, Fig. 5). This ensures a constant time t ₂ -t ₃ , which is very important for good energy stability of the generated pulses.

Claims (5)

DEFINITION OF INVENTION 1. A short-light pulse generator having a fully reflective mirror, a quality modulator, a first polarizer, a carrier medium, an aperture and an exit mirror disposed on a single optical axis, and further comprising a phase-shifting element, a lens and Brillouin active medium characterized in that it has a polarization control unit with a high-speed photo receiver and an electrical pulse generator electrically coupled to the storage device, said quality modulator being controlled by a signal from a polarization control unit whose control inputs are respectively electrically connected to the outputs of the pulse generator the input of the photoelectric is optically coupled to the first polarizer, and the first quarter-wave plate is positioned behind the first polarizer in the optical axis, and behind the active medium a second quarter-wave plate, a spectrum narrowing element placed in front of the exit mirror, a second polarizer positioned behind the exit mirror in the optical axis, and a variable or fixed focus lens. 2. The generator of claim 1, wherein the controlled quality modulator comprises first and second electro-optical crystals disposed on the optical axis between the fully reflecting mirror and the first polarizer, and the polarization control unit comprises two separate polarization control units, wherein the output of the first with an electro-optical crystal and an input with a pulse generator, the output of the second being electrically coupled to a second electro-optical crystal, and the inputs with a pulse generator and a high-speed photo receiver having an input optically coupled to the first polarizer, respectively. 3. The generator of claim 1, wherein the quality modulator is comprised of a single multi-electrode electro-optical crystal controlled from a single polarization control unit, the first input electrically coupled to the pulse generator output directly and the second input electrically coupled to the pulse generator via an additional polarization control unit. and directly coupled to a high-speed photo camera whose input is optically coupled to the first polarizer. 4. Generator according to claims 1-3, characterized in that the spectrum narrowing element is placed in a thermostat. 5. A generator according to claims 1-4, characterized in that the spectrum narrowing element and the output mirror comprise a single output mirror having spectrum narrowing properties.