RU2064721C1 - Frequency-stabilized gas laser - Google Patents

Abstract

FIELD: laser devices. SUBSTANCE: design of interface unit of excitation circuit of gas laser provides possibility to adjust matching and has control input. Multiplier and integrator are introduced in device circuit. In longitudinal direction system of electrodes is separated into at least two parts which have independent excitation circuits. EFFECT: increased stability of output frequency. 4 cl, 3 dwg

Description

 The invention relates to laser technology, in particular to a device for gas lasers with stabilization of the radiation frequency, and can be used to create laser local oscillators, including in mobile optical communication systems and locations.

 Known devices of frequency-stabilized RF-pumped gas lasers using photodetectors to obtain an error signal in the frequency stabilization system [1] These devices, especially for infrared lasers, have large dimensions, complicated optical circuits, and usually require cooled photodetectors, which limits their area laboratory research applications.

 A device for stabilizing the frequency of a laser with radio frequency excitation, using the opto-galvanic effect (OGE). The device contains an optical resonator, a system of electrodes for exciting an active medium, a pump generator, a matching device, means for extracting a signal reflected from the matching device, and an error signal processing circuit and controlling the frequency of the optical resonator (SOU) (prototype) [2] In this device, a modulating signal, produced by the SOA, leads to modulation of the optical field in the laser cavity and, therefore, to the modulation of the impedance of the laser plasma due to the OGE. A change in the plasma impedance causes modulation of the reflection coefficient of the high-frequency signal of the pump generator from the matching device. This modulation is fixed in the device to receive an error signal.

где

коэффициент отражения.The known device has inherent disadvantages caused by the following reasons. As you know, any high-frequency generator is also a noise source, the spectrum of which is concentrated near the central frequency of generation, and the intensity is usually of the order of -60 dB (10 ^-3 ) of the intensity at the central frequency of the RF generator. In the known device for stabilizing the frequency of the laser, information about the shift of the laser radiation frequency in the form of the amplitude and phase of the signal with the modulation frequency of the laser resonator is contained only in the signal reflected from the matching device. At the point of placement of the reflected signal extraction means (for example, a circulator), the error signal for a CO ₂ laser has a value of the order of 2 • 10 ^-5 • U _gn V / MHz, where U _{gn is the} amplitude of the output voltage of the pump generator. When modulating the optical resonator according to the harmonic law in the linear region of variation of its frequency, the reflected signal has the value

Where

reflection coefficient.

где Z_гн выходное сопротивление генератора накачки;
Z_су (1+m)•Z_гн;
Z_су входное сопротивление согласующего устройства в отсутствие модуляции оптического резонатора;
m коэффициент рассогласования генератора накачки и согласующего устройства;
K коэффициент ОГЭ;
Ω частота модуляции оптического резонатора.

where Z _{g the} output impedance of the pump generator;
Z _su (1 + m) • Z _gn ;
Z _su input impedance matching device in the absence of modulation of the optical resonator;
m is the mismatch coefficient of the pump generator and matching device;
K coefficient of OGE;
Ω modulation frequency of the optical resonator.

For m <1 and K <1, we have
P _neg = 0.5 • k • cosΩt + 0.5m;
U _neg = 0.5 • U _gn • (k • cosΩt + m).
Thus, noise from the pump generator proportional to the mismatch coefficient of the pump generator and matching device is introduced into the error signal isolation path. With a real value of this coefficient of the order of 0.2, the noise intensity in the error signal path is 10 ⁻⁴ U _gn B. The mismatch coefficient can change during laser operation due to a change in the power of the pump generator and the pressure of the gas mixture. Among the disadvantages of the known device should be attributed to the fact that the amplitude detection used in it can be performed only if there is a sufficient amplitude in the reflected signal of the carrier frequency, that is, when the pump generator and the matching device are mismatched. Thus, in the case of full (optimal) matching, corresponding to the maximum transmitted pump power, the frequency stabilization device becomes inoperative. Thus, a disadvantage of the known device is the limited stability of the laser radiation frequency due to the presence of unrecoverable noise in the path of the error signal.

 The purpose of the invention is to increase the stability of the laser radiation frequency by improving the signal-to-noise ratio in the error signal isolation path.

 The goal is achieved in a frequency-stabilized gas laser with radio frequency excitation, containing an optical resonator, a system of exciting electrodes, a pump generator, a matching device, means for extracting the reflected signal (circulator), and an error signal processing and frequency control circuit of the optical resonator (SOU), as follows. The matching device is designed so that it allows adjustment of matching, for example, using varicaps installed in the shoulders of the L-shaped filter. In addition, a multiplier and an integrator are introduced, and the voltage from the reflected signal extraction means, for example, a circulator, is applied to the first input of the multiplier, and the voltage with the frequency of the pump generator is supplied to the second input, the output of the multiplier is connected to the input of the SDA and the integrator, the output of which is connected to the control input of the matching device Fig. 1). This circuit allows you to eliminate the mismatch between the pump generator and the matching device, thereby reducing the noise level in the path of the error signal and, therefore, increasing the stability of the laser radiation frequency.

 The novelty of the technical solution is determined by the use of a series-connected multiplier and an integrator connected to the control input of an adjustable matching device in a frequency-stabilized laser with radio-frequency excitation. At the same time, the voltage from the means for extracting the reflected signal and the voltage with the frequency of the pump generator are supplied to the inputs of the multiplier, and an error signal is fed to the input of the JMA from the output of the multiplier. The claimed technical solution contains the following significant differences: in a laser with radio frequency excitation, the voltage obtained by amplitude-phase detection of the reflected signal is used for two purposes to automatically adjust the length of the optical resonator using the SDA by the modulation method and to automatically adjust the matching of the pump generator with the laser discharge by DC component of the selected voltage. For the first time, this technical solution uses auto-tuning of matching to minimize noise in the path of extracting the error signal for the SDA of a frequency-stabilized laser with radio frequency excitation. Since the dispersion of the frequency error is directly proportional to the spectral density of the noise at the modulation frequency of the optical resonator, a decrease in noise leads to an increase in the stability of the laser radiation frequency.

 In a laser according to claim 2 of the formula, a reflectometer (incident and reflected signal sensor) is used as a means of isolating the signal reflected from the matching device, and from its two outputs the signals are supplied respectively to the two inputs of the multiplier. This technical solution allows you to abandon the relatively expensive circulator and get rid of unwanted phase shifts between the signals supplied to the inputs of the multiplier.

раз. Это происходит, поскольку в предположении наличия в полосе пропускания системы "белого" шума при сложении двух одинаковых сигналов на выходе сумматора напряжение шума увеличивается в

раз по сравнению с каждым из складываемых сигналов, а амплитуда полезного сигнала ошибки увеличивается в 2 раза.In a laser according to claim 3, the system of electrodes for exciting an active medium is longitudinally divided into at least two parts with independent excitation paths. In this case, an adder was additionally introduced, the inputs of which are connected to the outputs of the multipliers of each excitation path, and the output is connected to the input of the SDA (Fig. 2). Such a design of the circuit allows the use of separate pump generators without the need to apply high-frequency addition of power and equalize the high-frequency potential along the entire length of the electrode system to excite the active medium, and also allows to increase the signal-to-noise ratio in the signal path of the error signal in

time. This happens because, assuming that there is “white” noise in the system bandwidth when two identical signals are added at the adder output, the noise voltage increases by

times compared with each of the added signals, and the amplitude of the useful error signal increases by 2 times.

In FIG. 1 is a block diagram of a frequency stabilized gas laser with radio frequency excitation according to claim 1; figure 2 is a block diagram of a frequency-stabilized laser with a longitudinally divided system of electrodes of radio frequency excitation according to claim 3; figure 3 the dependence of the reflection coefficient on the input impedance of the matching device in the vicinity of the point Z _GL .

 The device according to claim 1, contains an optical resonator 1, an electrode system for exciting an active medium 2, a matching device 3 with a control input 4, means for extracting a signal 5 reflected from the matching device, a pump generator 6, a multiplier 7, an integrator 8, and an error signal processing circuit, and controlling the frequency of the optical resonator (SOU) 9, including a phase detector 10, an integrating device of the SOU 11, an amplifier 12, a modulating generator 13, a summing device of the SOU 14 and a piezoelectric element for adjusting the length of the resonator 15, on which akrepleno one of the resonator mirrors 16.

 The device according to claim 3 further comprises an adder 17.

 A frequency-stabilized gas laser operates as follows: from a radio-frequency pump generator 6, a traveling wave of an electromagnetic field propagates towards the electrode system to excite an active medium 2, the input resistance of which is matched to the output resistance of the pump generator using a matching device 3. Forced modulation of the optical resonator 1 by a piezoelectric element 15 with a mirror 16 mounted on it, leads to modulation of the optical field in the cavity, and therefore reflected from signal matching device. The reflected signal is emitted by the circulator 5 installed between the pump generator and the matching device. The amplitude-phase detection of the reflected signal is carried out by a multiplier 7, to one input of which a reference voltage is supplied from the output of the pump generator, and to the other input, the reflected signal from the circulator. The signal with the frequency of the forced modulation from the output of the multiplier is fed to the input of the SOU 9, in which it is compared on the phase detector 10 with the reference voltage of the modulation frequency from the generator 13, is integrated by the integrating device of the SOU 11, amplified by a DC amplifier 12, and fed to the summing device of the SOU 14, generating a control signal for setting the frequency of the optical resonator to the center of the gain circuit of the active medium using a piezoelectric element 15, the constant component of the voltage from the output will multiply Spruce 7 is fed to the integrator 8 and then to the control input 4 of the matching device to adjust the matching in order to minimize the constant voltage at the output of the multiplier.

If the input resistance of the matching device Z _{cu is} greater than the output resistance of the pump generator Z _gn , the constant component at the output of the multiplier is positive, the feedback circuit works to decrease Z _cu , with Z _cu <Z _{cn the} constant component is negative, the OS circuit works to increase Z _cu . When minimizing the DC component at the output of the multiplier, the level of noise introduced from the pump generator decreases proportionally, and the signal-to-noise ratio in the path of the selection of the error signal for the SDA increases. The dispersion of the frequency error is directly proportional to the spectral density of the noise at the modulation frequency of the optical resonator; therefore, a decrease in the noise level leads to an increase in the stability of the laser radiation frequency.

When implementing a frequency-stabilized laser with radio frequency excitation, an all-metal laser based on a CO ₂ -N ₂ -He mixture made of 32 NKD alloy (super-invar) is used, one of the mirrors in which is mounted on a KP-1 piezoelectric corrector. A 100 W transistor generator operating at an industrial frequency of 81.6 MHz is used to pump the laser. As a matching device, a L-shaped filter with shoulder conductivities that can be changed using varicaps is used. The range of this change is about 10%. To isolate the signal reflected from the matching device, an OTDR (incident and reflected sensor) is used, constructed according to the scheme using a current transformer. High-frequency voltages from both of its outputs, proportional to the incident and reflected signals, are supplied to an annular balanced mixer used as a multiplier and loaded onto a low-pass filter with a cutoff frequency of 5 kHz. The integrator in the auto-tuning matching circuit has a time constant of about 0.5 s and is built on an operational amplifier (op amp) 140 UD7. The sine-wave modulation signal generator of the SDA processing and control circuit has a frequency of about 600 Hz, the SDA has a transmission coefficient of 2 • 10 ⁶ and the time constant of the SDA integrating device is about 1 s. When constructing a frequency-stabilized laser with a longitudinally divided radio-frequency excitation system (claim 3 of the claims), an adder on OA 140 UD7 is used.

It was experimentally established that when the mismatch coefficient of the pump generator with the matching device is reduced by a factor of 3 due to the auto-matching circuit, the spectral density of noise introduced into the signal processing path of the error from the pump generator is reduced by a factor of 3 and, therefore, the frequency error dispersion is reduced by a factor of 3. frequency-stabilized laser due to the amplitude noise of the pump generator. The high effect achieved in RF pumped lasers is explained by the low intrinsic noise of the laser plasma excited by a high-frequency discharge. Thus, the use of the claimed invention will significantly improve the stability of gas CO ₂ lasers with radio frequency pumping, used as local oscillators in the technique of laser communication and location.

Claims (3)

 1. A frequency-stabilized gas laser with radio frequency excitation, comprising an optical resonator, an electrode system for exciting an active medium, a pump generator, a matching device, a reflection signal extraction unit, an error signal processing circuit and an optical resonator frequency control circuit, characterized in that, in order to increasing the stability of the laser radiation frequency by improving the signal-to-noise ratio in the error signal isolation path, an additional multiplier and an integrator are introduced, the first input the multiplier is connected to the output of the reflected signal extraction unit, and the second input to the output of the pump generator, the output of the multiplier is connected to the error signal processing circuit and the frequency control of the optical resonator and to an integrator, the output of which is connected to the control input of the matching device.  2. The laser according to claim 1, characterized in that the reflectometer is used as a block for highlighting the reflected signal and its outputs are connected to the inputs of the multiplier.  3. The laser according to claim 1, characterized in that the electrode system for exciting the active medium is longitudinally divided into at least two parts with independent excitation paths, an adder is additionally introduced, the inputs of which are connected to the outputs of the multipliers of each excitation path, and the output with the input of the error signal processing circuit and the frequency control of the optical resonator.

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