CN102545026B - System and method capable of realizing energy stability of injected laser - Google Patents

Abstract

The invention relates to a system and a method capable of realizing energy stability of injected laser. The system is connected with an external injection fiber and comprises a first light split unit, a Lambda/2 wave plate, a second light split unit, an energy monitoring device, a delay device, an optical rotation device, a third light split unit and an electric control device, wherein the input light from the injection fiber is changed to a first horizontal polarized light by the first light split unit, is rotated at a preset angle Theta by the Lambda/2 wave plate and is then split into a first polarized light and a second polarized light by the second light split unit, the first polarized light enters the energy monitoring device, the delay device receives and transmits the second polarized light in a delayed manner, the electric control device receives the energy E monitoring of the first polarized light and generates an optical rotation angle Beta according to the energy E monitoring, and the optical rotation device carries out optical rotation according to the angle Beta; and the third light split unit receives the second polarized light after optical rotation and outputs a second horizontal polarized light. According to the system and the method, the stability of pulse laser outputted by the system along with the time change is ensured, and the stable gain of the laser pulse is further realized.

Description

Realize injecting the stable system and method for laser energy

Technical field

The present invention relates to the laser application technique field, particularly a kind of electrooptic crystal that utilizes realizes injecting the stable system and method for laser energy.

Background technology

Electrooptical switching is a very important device in the laser, its application is an important breakthrough on the laser development history, it makes the monochromatic brightness of laser improve several orders of magnitude, has also promoted the development of application technologies such as laser ranging, laser radar, high speed holographic and laser processing simultaneously.Its principle is to utilize the effect of external electric field to make the change of the refractive index generating period of crystal: uniaxial crystal periodically becomes biaxial crystal under effect of electric field, or the change of the shape of the index ellipsoid of biaxial crystal and orientation generating period, electrooptical switching makes the light generation birefringence by crystal change the polarization polarization state of light, uses the modulation that just can realize light with polarizer.The electrooptical switching technology is by change the Q value of resonant cavity in the oscillatory process of laser, to produce the laser of high-peak power, narrow pulse width.Compare with acoustooptic switch, electrooptical switching is widely used in solid state laser because having efficient height, fast, the narrow and peak power advantages of higher of output laser pulse width of switching speed.

The pulse laser that the laser front end injects, energy are unstable usually, as shown in Figure 1.The laser energy of laser output can fluctuate up and down along with the instability of the laser energy that injects, the unsettled laser of laser energy is through behind some Optical Maser Systems, this unsteadiness in addition can be exaggerated a lot of doubly, and make the unsteadiness of the laser energy of laser output become violent unusually.

Summary of the invention

Main contents of the present invention are to provide a kind of stable system and method for laser energy of realizing injecting, and are intended to improve the stability of laser output laser energy.

In order to achieve the above object, the present invention proposes a kind of stable system of laser energy that realizes injecting, and is connected with outside injection fibre, and described system comprises:

First spectrophotometric unit be used for to receive the input light of described outside injection fibre, and described input light is become the first horizontal linear polarization light;

λ/2 wave plates is used for receiving the described first horizontal linear polarization light, and with described first horizontal linear polarization light rotation predetermined angle theta;

Second spectrophotometric unit be used for to receive the postrotational first horizontal linear polarization light, and is divided into first polarised light and second polarised light is exported;

The energy monitoring device is used for receiving described first polarised light, and monitors the energy E of first polarised light _Prison

Deferred mount is used for receiving and postpones to transmit described second polarised light;

Electric control gear is for the energy E that receives described first polarised light _Prison, and according to the energy E of described first polarised light _PrisonProduce the optically-active angle beta;

The optically-active device is used for receiving described second polarised light, and carries out optically-active according to described angle beta; And

The 3rd spectrophotometric unit for second polarised light after the reception optically-active, and is exported the second horizontal linear polarization light.

Preferably, described predetermined angle theta refers to the incident vibration plane of input light of described λ/2 wave plates and the angle between the optical axis, wherein, and 0≤θ≤90.

Preferably, described first spectrophotometric unit, second spectrophotometric unit and the 3rd spectrophotometric unit are polarization splitting prism.

Preferably, described optically-active device is electrooptical switching.

Preferably, described first polarised light and described second polarised light are respectively perpendicular linear polarization light and the 3rd horizontal linear polarization light.

Preferably, described electric control gear also is used for suspending earlier described optically-active device, and according to the energy E of described first polarised light _Prison, the least energy E of the 3rd horizontal linear polarization light of described deferred mount output in the calculating scheduled time Δ t _Min, open described optically-active device, according to described least energy E _MinObtain the voltage V that is added on the described optically-active device, make the energy of the described second horizontal linear polarization light of described the 3rd spectrophotometric unit output keep least energy E in the Δ t at the fixed time _Min

Preferably, E _Min=E _{Prison min}/ tg ²2 θ; Wherein,

E _{Prison min}The energy E of the perpendicular linear polarization light that measures for scheduled time Δ t self-energy monitoring arrangement _PrisonMinimum value.

Preferably, the described voltage V=F (β) that is added on the optically-active device, wherein,

The present invention also proposes a kind of stable method of laser energy that realizes injecting, and may further comprise the steps:

First spectrophotometric unit receives the input light that outside injection fibre injects by coupling head, and described input light is become the first horizontal linear polarization light, exports λ/2 wave plates to;

Described λ/2 wave plates export the horizontal linear polarization light rotation predetermined angle theta that receives to second spectrophotometric unit;

Described second spectrophotometric unit is isolated first polarised light and second polarised light from the linearly polarized light that receives, and the described first polarised light branch is delivered to the energy monitoring device, and the described second polarised light branch is delivered to deferred mount;

The energy monitoring device receives described first polarised light, and monitors the energy E of first polarised light _Prison

Deferred mount receives and delay transmits described second polarised light;

Electric control gear receives the energy E of described first polarised light _Prison, and according to the energy E of described first polarised light _PrisonProduce the optically-active angle beta;

The optically-active device receives described second polarised light, and carries out optically-active according to described angle beta;

The 3rd spectrophotometric unit receives second polarised light after the optically-active, and exports the second horizontal linear polarization light.

Preferably, described predetermined angle theta refers to the incident vibration plane of input light of described λ/2 wave plates and the angle between the optical axis, wherein, and 0≤θ≤90.

Preferably, described first spectrophotometric unit, second spectrophotometric unit and the 3rd spectrophotometric unit are polarization splitting prism.

Preferably, described optically-active device is electrooptical switching.

Preferably, described first polarised light and described second polarised light are respectively perpendicular linear polarization light and the 3rd horizontal linear polarization light.

Preferably, the step that produces described optically-active angle beta comprises:

Described electric control gear is according to the measurement result E of described energy monitoring device _Prison, the least energy E of the 3rd horizontal linear polarization light of described deferred mount output in the calculating scheduled time Δ t _MinAnd

Described electric control gear is according to described least energy E _MinObtain the voltage V that is added on the described optically-active device, make the energy of the second horizontal linear polarization light of described the 3rd spectrophotometric unit output keep least energy E in the Δ t at the fixed time _Min

Preferably, E _Min=E _{Prison min}/ tg ²2 θ; Wherein,

E _{Prison min}The energy E of the perpendicular linear polarization light that measures for scheduled time Δ t self-energy monitoring arrangement _PrisonMinimum value.

Preferably, the described voltage V=F (β) that is added on the optically-active device, wherein,

The present invention proposes a kind ofly realizes injecting the stable system and method for laser energy, measurement by the energy monitoring device and electric control gear are to the control of optically-active device, obtain the least energy Emin that passes through the horizontal linear polarization light of deferred mount in the scheduled time Δ t, with this least energy Em _InBe standard, and by electric control gear control, adjust the voltage that is added on the optically-active device, make by the optically-active device and through the energy of the horizontal linear polarization light of the 3rd spectrophotometric unit output and remain on least energy E _MinThereby, guaranteed the time dependent stability of exporting of pulse laser, further realize the constant gain of laser pulse.

In order to make technical scheme of the present invention clearer, clear, be described in further detail below in conjunction with accompanying drawing.

Description of drawings

Fig. 1 is that existing laser injects the laser energy time history plot;

Fig. 2 is that the present invention realizes injecting the stable system of laser energy one example structure schematic diagram;

Fig. 3 is the incident vibration plane of the present invention's input light of realizing injecting the one embodiment λ of the stable system of laser energy/2 wave plates and the angle structural representation between the optical axis;

Fig. 4 is that the present invention realizes injecting a kind of execution mode structural representation of one embodiment of the stable system of laser energy;

Fig. 5 is that the present invention realizes injecting one embodiment of the stable system of laser energy by the amplitude decomposing schematic representation of the linearly polarized light behind the electrooptic crystal;

Fig. 6 is that the present invention realizes injecting one embodiment of the stable system of laser energy and injects laser energy and keep stable schematic diagram in time;

Fig. 7 is that the present invention realizes injecting the stable method of laser energy one embodiment schematic flow sheet;

Fig. 8 is that the present invention realizes injecting the schematic flow sheet that the stable method of laser energy one embodiment produces the optically-active angle beta.

Embodiment

As shown in Figure 2, one embodiment of the invention proposes a kind of stable system of laser energy that realizes injecting, be connected with outside injection fibre 1, this system comprises: first spectrophotometric unit 3, λ/2 wave plates 4, second spectrophotometric unit 5, deferred mount 6, energy monitoring device 9, optically-active device 7, the 3rd spectrophotometric unit 8 and be connected the electric control gear 10 that is used for control optically-active device 7 with optically-active device 7, wherein:

First spectrophotometric unit 3 be used for to receive the input light of outside injection fibre, and will import light and become the first horizontal linear polarization light.

λ/2 wave plates 4 is used for receiving the first horizontal linear polarization light, and with first horizontal linear polarization light rotation predetermined angle theta.

Second spectrophotometric unit 5 be used for to receive the postrotational first horizontal linear polarization light, and is divided into first polarised light and second polarised light is exported.

Energy monitoring device 9 is used for receiving first polarised light, and monitors the energy E of first polarised light _Prison

Deferred mount 6 is used for receiving and postpones to transmit second polarised light.

Electric control gear 10 be used for to receive the energy E prison of first polarised light, and according to the energy E of first polarised light _PrisonProduce the optically-active angle beta.

Optically-active device 7 is used for receiving second polarised light, and carries out optically-active according to angle beta.

The 3rd spectrophotometric unit 8 for second polarised light after the reception optically-active, and is exported the second horizontal linear polarization light.

In the present embodiment, first spectrophotometric unit 3 is connected by coupling head 2 with outside injection fibre 1; Second spectrophotometric unit, 5 one outputs are connected with deferred mount 6, and its another output is connected with energy monitoring device 9; λ/2 wave plates 4 are connected between first spectrophotometric unit 3 and second spectrophotometric unit 5.

Particularly, first spectrophotometric unit 3, second spectrophotometric unit 5 and the 3rd spectrophotometric unit 8 are PBS (polarization splitting prism) in the present embodiment.

As shown in Figure 3, incident vibration plane and the angle between the optical axis of the input light of λ/2 wave plates 4 are θ, 0≤θ≤90.

Wave plate, be called phase delay chip again, it makes the amount of polarization by two mutually orthogonals of wave plate produce phase deviation, can be used to adjust the polarization state of light beam, the major parameter of wave plate comprises wavelength, phase place, bore and wave plate type (zero level or multistage), common wave plate is made by quartz crystal, be mainly 1/2nd and quarter-wave plate be λ/2 wave plates and λ/4 wave plates.

Linearly polarized light is by behind λ/2 wave plates, it still is linearly polarized light, but, it closes the vibration plane of vibration and the vibration plane of incident ray polarized light turns over 2 θ, if θ=45 degree, then the vibration plane of emergent light is vertical with the vibration plane of former incident light, that is to say, when θ=45 were spent, λ/2 wave plates can make polarization state revolve and turn 90 degrees.

When the angle theta of the incident vibration plane of polarised light and wave plate optical axis is 45 when spending, the light by λ/4 wave plates is circularly polarized light, otherwise, when circularly polarized light through behind λ/4 wave plates, then become linearly polarized light.When twice of light during by λ/4 wave plates, effect is equivalent to a λ/2 wave plates.λ/4 wave plates can also be used with PBS, realize the effect of optical isolator.

Above-mentioned optically-active device 7 can be electrooptical switching.In the present embodiment, the added voltage difference of electrooptic crystal that electric control gear 10 is given in the electrooptical switching, its character that shows are also different.For example, add λ/2 voltages, electrooptic crystal shows the character of λ/2 wave plates; Add λ/4 voltage electrooptic crystals and show the character of λ/4 wave plates, add the voltage of the λ of how many branches, electrooptic crystal just shows the character of wave plate of the λ of how many branches, realizes the bit phase delay of o light and e light, thereby changes the energy of light.

As shown in Figure 4, be that electrooptical switching, first spectrophotometric unit 3 are that PBS1, second spectrophotometric unit 5 are that PBS2, second light-dividing device 8 are that PBS3 is example and elaborates the operation principle that present embodiment realizes injecting the stable system of laser energy in conjunction with Fig. 2 and Fig. 3 with optically-active device 7 below:

Inject light and by coupling head 2 pulse laser is injected the PBS1 of present embodiment system, PBS1 becomes laser into the first horizontal linear polarization light, the first horizontal linear polarization light is by behind λ/2 wave plates 4, according to linear polarization rotation minute angle θ as shown in Figure 3, dotted line is represented the direction of vibration before the first horizontal linear polarization light passes through λ/2 wave plates 4 among Fig. 3, and solid line represents that the first horizontal linear polarization light is through the direction of vibration behind λ/2 wave plates 4.

Behind the postrotational first horizontal linear polarization light process of λ/2 wave plates PBS2, the perpendicular linear polarization light that sub-fraction laser is namely separated from the first horizontal linear polarization light enters energy monitoring device 9, the 3rd horizontal linear polarization light that most of laser is namely separated from the first horizontal linear polarization light continues back kick by deferred mount 6 backs and broadcasts, pass through electrooptical switching, after crossing PBS3, the energy stabilization of the second horizontal linear polarization light of output.

The energy stabilization of the second horizontal linear polarization light of PBS3 output is that the control by 10 pairs of electrooptical switchinges of electric control gear realizes.

At first need to obtain by the measurement result of energy monitoring device 9 the least energy Emin of deferred mount 6 outputs in the Δ t at the fixed time, be standard with this least energy Emin then, calculate in the scheduled time Δ t certain constantly t should be added in magnitude of voltage V on the electrooptical switching so that the second horizontal linear polarization light of PBS3 output at the fixed time the energy in the Δ t preserve stationary value Emin.

Wherein: Emin=E _{Prison min}/ tg ²2 θ, in the formula, E _{Prison min}The energy E of the perpendicular linear polarization light that measures for scheduled time Δ t self-energy monitoring arrangement 9 _PrisonMinimum value, with the standard energy value of Emin as present embodiment system stability output laser.

V=F (β), wherein,

β is by the vibration plane of the linearly polarized light behind the electrooptical switching and the angle of optical axis.

The computational process of β is as follows:

If the energy of the linearly polarized light by deferred mount 6 is E _Prolong, then have

E _Prolong=E _Prison/ tg ²2 θ, (1)

As shown in Figure 5, by entering the amplitude A of the linearly polarized light of electrooptic crystal in the electrooptical switching behind the deferred mount 6 _ProlongCan be decomposed into horizontal direction and vertical direction,

A _ProlongCos β=A _Level(2)

Thus, can obtain

E _ProlongCos ²β=E _Level(3)

The energy stabilization of preserving the horizontal linear polarization light of PBS3 output is Emin, then makes E in above-mentioned (3) formula

_Level=Emin

Then,

E _ProlongCos ²β=Emin (4)

Obtain according to above-mentioned (1) and (4) formula

Last according to the functional relation V=F (β) that is scheduled to that is added in voltage and β on the electrooptic crystal, interior certain moment t of scheduled time Δ t can be obtained and the magnitude of voltage V on the electrooptic crystal in the electrooptical switching should be added in, the Emin thereby the energy of the second horizontal linear polarization light of assurance PBS3 output remains stable.

Acting as of deferred mount 6 wherein: 9 monitorings of energy monitoring device are analyzed the laser energy in the Δ t time, carry out respective handling by electric control gear 10 again, make deferred mount 6 laser need be postponed Δ t.

By the linearly polarized light after the present embodiment system handles because its energy Emin that remains stable, therefore, it is highly stable that pulse laser to be injected is changed in time, as shown in Figure 6, the pulse laser that this is stable reinjects in the laser amplifier, can realize the constant gain of laser pulse.

As shown in Figure 7, one embodiment of the invention proposes a kind of stable method of system's realization injection laser energy in above-described embodiment of utilizing, and comprising:

Step S101, first spectrophotometric unit receive the input light that outside injection fibre injects by coupling head, and will import light and become horizontal linear polarization light, export λ/2 wave plates to;

Step S102, λ/2 wave plates export the horizontal linear polarization light rotation predetermined angle theta that receives to second spectrophotometric unit;

Step S103, second spectrophotometric unit is isolated first polarised light and second polarised light from the linearly polarized light that receives, and the first polarised light branch is delivered to the energy monitoring device, and the second polarised light branch is delivered to deferred mount;

Step S104, the energy monitoring device receives first polarised light, and monitors the energy E of first polarised light _Prison

Step S105, deferred mount receive and delay transmits second polarised light;

Step S106, electric control gear receive the energy E of first polarised light _Prison, and according to the energy E of first polarised light _PrisonProduce the optically-active angle beta;

Step S107, the optically-active device receives second polarised light, and carries out optically-active according to angle beta;

Step S108, the 3rd spectrophotometric unit receives second polarised light after the optically-active, and exports the second horizontal linear polarization light.

Above-mentioned predetermined angle theta refers to the incident vibration plane of input light of λ/2 wave plates and the angle between the optical axis, wherein, and 0≤θ≤90.

First spectrophotometric unit, second spectrophotometric unit and the 3rd spectrophotometric unit are polarization splitting prism in the present embodiment.

Above-mentioned first polarised light and second polarised light are respectively perpendicular linear polarization light and the 3rd horizontal linear polarization light.

As shown in Figure 8, the step of generation optically-active angle beta comprises among the step S106:

Step S1061, electric control gear is according to the measurement result E of energy monitoring device _Prison, the least energy E of the 3rd horizontal linear polarization light of deferred mount output in the calculating scheduled time Δ t _Min

Step S1062, electric control gear is according to least energy E _MinObtain the voltage V that is added on the optically-active device, make the energy of the second horizontal linear polarization light of the 3rd spectrophotometric unit output keep least energy E in the Δ t at the fixed time _Min

Above-mentioned E _Min=E _{Prison min}/ tg ²2 θ; Wherein, E _{Prison min}The energy E of the perpendicular linear polarization light that measures for scheduled time Δ t self-energy monitoring arrangement _PrisonMinimum value.

Above-mentionedly be added in the voltage V=F (β) on the electrooptic crystal in the optically-active device, wherein,

In the present embodiment, the optically-active device can be electrooptical switching.In the present embodiment, electric control gear is given the added voltage difference of electrooptic crystal in the electrooptical switching, and the character that electrooptic crystal shows is also different.The voltage that adds the λ of how many branches, electrooptic crystal just show the character of wave plate of the λ of how many branches, realize the bit phase delay of o light and e light, thereby change the energy of light.

The embodiment of the invention proposes a kind ofly realizes injecting the stable system and method for laser energy, measurement by the energy monitoring device and electric control gear be to the control of optically-active device, obtains in the scheduled time Δ t least energy E by the horizontal linear polarization light of deferred mount _Min, with this least energy E _MinBe standard, and by electric control gear control, adjust and be added in the voltage on the electrooptic crystal in the optically-active device, make by the optically-active device and through the energy of the horizontal linear polarization light of second light-dividing device output and remain on least energy E _MinThereby, guaranteed the time dependent stability of exporting of pulse laser, further realize the constant gain of laser pulse.

The above only is the preferred embodiments of the present invention; be not so limit claim of the present invention; every equivalent structure or flow process conversion that utilizes specification of the present invention and accompanying drawing content to do; or directly or indirectly be used in other relevant technical field, all in like manner be included in the scope of patent protection of the present invention.

Claims (8)

1. realize injecting the stable system of laser energy for one kind, be connected with outside injection fibre, it is characterized in that, described system comprises: first spectrophotometric unit, λ/2 wave plates, second spectrophotometric unit, energy monitoring device, deferred mount, electric control gear, optically-active device and the 3rd spectrophotometric unit, wherein

First spectrophotometric unit is used for receiving the input light of described outside injection fibre, and described input light is become the first horizontal linear polarization light;

λ/2 wave plates are used for receiving the described first horizontal linear polarization light, and with described first horizontal linear polarization light rotation predetermined angle theta;

Second spectrophotometric unit be used for to receive the postrotational first horizontal linear polarization light, and is divided into first polarised light and second polarised light is exported, and described first polarised light and second polarised light are respectively perpendicular linear polarization light and the 3rd horizontal linear polarization light;

The energy monitoring device is used for receiving described first polarised light, and monitors the energy E of first polarised light _Prison

Deferred mount is used for receiving and postpones to transmit described second polarised light;

Electric control gear is used for receiving the energy E of described first polarised light _Prison, and according to the energy E of described first polarised light _PrisonProduce the optically-active angle beta, apply voltage V at described optically-active device, make the energy of the polarised light of described the 3rd spectrophotometric unit output keep least energy E in the Δ t at the fixed time _Min, V=F(β wherein), F is for applying the voltage predefined function,

The least energy E of the 3rd horizontal linear polarization light of described deferred mount output in the scheduled time Δ t _Min=E _{Prison min}/ tg ²2 θ, E _{Prison min}The energy E of the perpendicular linear polarization light that measures for scheduled time Δ t self-energy monitoring arrangement _PrisonMinimum value;

The optically-active device is used for receiving described second polarised light, carries out optically-active according to described angle beta under the effect of voltage V; And

The 3rd spectrophotometric unit for second polarised light after the reception optically-active, and is exported the second horizontal linear polarization light.

2. system according to claim 1 is characterized in that, described predetermined angle theta refers to the incident vibration plane of input light of described λ/2 wave plates and the angle between the optical axis, wherein, and 0≤θ≤90.

3. system according to claim 2 is characterized in that, described first spectrophotometric unit, second spectrophotometric unit and the 3rd spectrophotometric unit are polarization splitting prism.

4. system according to claim 3 is characterized in that, described optically-active device is electrooptical switching.

5. realize injecting the stable method of laser energy for one kind, it is characterized in that, may further comprise the steps:

First spectrophotometric unit receives the input light that outside injection fibre injects by coupling head, and described input light is become the first horizontal linear polarization light, exports λ/2 wave plates to;

Described λ/2 wave plates export the horizontal linear polarization light rotation predetermined angle theta that receives to second spectrophotometric unit;

Described second spectrophotometric unit is isolated first polarised light and second polarised light from the linearly polarized light that receives, and the described first polarised light branch delivered to the energy monitoring device, the described second polarised light branch is delivered to deferred mount, and described first polarised light and second polarised light are respectively perpendicular linear polarization light and the 3rd horizontal linear polarization light;

The energy monitoring device receives described first polarised light, and monitors the energy E of first polarised light _Prison

Deferred mount receives and delay transmits described second polarised light;

Electric control gear receives the energy E of described first polarised light _Prison, and according to the energy E of described first polarised light _PrisonProduce optically-active angle beta and voltage V, wherein V=F(β), F is for applying the voltage predefined function, The least energy E of the 3rd horizontal linear polarization light of described deferred mount output in the scheduled time Δ t _Min=E _{Prison min}/ tg ²2 θ, E _{Prison min}The energy E of the perpendicular linear polarization light that measures for scheduled time Δ t self-energy monitoring arrangement _PrisonMinimum value;

The optically-active device receives described second polarised light, carries out optically-active according to described angle beta under the effect of voltage V;

The 3rd spectrophotometric unit receives second polarised light after the optically-active, and exports the second horizontal linear polarization light.

6. method according to claim 5 is characterized in that, described predetermined angle theta refers to the incident vibration plane of input light of described λ/2 wave plates and the angle between the optical axis, wherein, and 0≤θ≤90.

7. method according to claim 6 is characterized in that, described first spectrophotometric unit, second spectrophotometric unit and the 3rd spectrophotometric unit are polarization splitting prism.

8. method according to claim 7 is characterized in that, described optically-active device comprise following one of at least: electrooptical switching, Faraday polarization apparatus, liquid crystal, have λ/2 wave plates of circulator.

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