KR20090102490A - Optical parametric oscillator laser that use pumping light which consist of orthogonal two polarized light - Google Patents

Abstract

PURPOSE: An optical parametric oscillator laser that uses a pumping light which consist of orthogonal two polarized lights is provided to amplify the output of a laser beam or output a laser beam having different wavelengths while minimizing the energy loss. CONSTITUTION: The pump light of a DPSS laser(1) is classified into a penetrated and polarized pump light(11) and a reflected and polarized pump light(12). An OPO laser beam having different wavelengths is outputted through an OPO(2) that satisfies a non-linear optical phase matching condition by using the split pump lights as a source.

Description

Optical Parametric Oscillator Laser that Use Pumping Light Which Consist of Orthogonal Two Polarized Light}

The present invention relates to an optical parametric oscillator (OPO) laser device using two orthogonal polarized pump light sources. In particular, the present invention relates to an oscillating pump light in which a light vibrating in two orthogonal directions, such as a diode pumped solid state (DPSS) laser, is mixed. The present invention relates to an OPO laser device that utilizes both pump lights separated by pump light of two polarizations.

As is well known, an OPO laser apparatus for outputting a laser having a desired wavelength from an ultraviolet region to an infrared region by passing a pump light source through an OPO has been known in the art, and is a representative example of Korean Patent No. 424553 (name of the invention: high power). OPIO laser device (hereinafter referred to as 'quotation invention'). As shown in FIG. 1, the cited invention includes a pumping laser 201, a beam reducer 203 for adjusting a beam of the pumping laser 201 to a beam size usable as pumping light, and the beam reducer 203. A first partial reflector 204 for reflecting the pumping light used for outputting the opio laser beam and transmitting the other pumping light to the beam dumps 205 and 211. The gain medium 207 for generating the opio laser beam through interaction with the pumping light, and of the pumping light output from the gain medium 207, the opio laser beam is transmitted, and the other pumping light is a beam dump ( A second partial reflector 209 reflecting back to 205 and 211, a resonator for reciprocating and amplifying the transmitted opio laser beam, and an idler beam 214 and a signal beam 213 for the amplified opio laser beam. Separated by) Is to include a prism (212).

The cited invention outputs an opio laser beam through a process in which the pumped light passing through the beam reducer 203 is reflected and transmitted through the first and second partial reflectors 204 and 209, and the opio laser is thus output. Since the light beam is amplified by the resonator composed of two mirrors 206 and 210, the pumping light does not directly enter the first and second mirrors 206 and 210 constituting the resonator, so that the first and second mirrors ( Since 206 and 210 are not damaged, even if the pumping is strong, the resonator is not damaged, and thus the high output opio laser beam is output.

However, the cited invention uses only a part of the pumping light output from the beam reducer 203 as an opio laser and transmits and dumps the remaining pumping light so that there is a lot of energy lost and only one type of laser is output. .

An object of the present invention is to solve the problem, because the pump light is mixed with two or more oscillating light in two orthogonal directions and two pump light is separated by using two separate pump light to output two kinds of wavelengths at the same time or To provide an opio laser that amplifies the output.

In order to achieve the above object, the present invention provides an OPO laser apparatus having a stable output of high efficiency through OPO using the pump light of a DPSS laser as a source. Orthogonal polarization pump light source, characterized in that the two pump light beams having the desired wavelength are simultaneously output through the OPO satisfying different nonlinear optical phase matching conditions using each separated pump light as a separate source. Opio laser device using,

An optical isolator (Optical Isolator or Faraday Rotator) which protects the DPSS laser from the reflected pump light and has a high efficiency and stable output through the OPO is provided as the source of the pump light of the DPSS laser. A polarization splitter is installed between the optical isolator to separate the pump light of DPSS into the transmission polarized pump light and the reflected polarized pump light, and the OPO satisfying different nonlinear optical phase matching conditions using each separated pump light as a source. An opio laser device using two orthogonal polarization pump light sources, characterized in that simultaneously outputting two OPO lasers,

In the intra-cavity OPO laser device in which the OPO is added inside the DPSS laser and has a stable output with high efficiency, the pump light in the aforementioned DPSS laser is transmitted and polarized by the polarization splitter and the pump light polarized by reflection. OP using two orthogonal polarized pump light sources, characterized in that simultaneously outputs two OPO lasers having desired wavelengths through OPO satisfying different nonlinear optical phase matching conditions using each separated pump light as a source. O Provide laser device.

Here, a reflecting mirror is provided after the polarizing splitter so that the reflected polarized pump light reflected from the aforementioned polarizing splitter proceeds in the same direction as the transmission polarized pump light. Each of the two OPO lasers described above which are simultaneously output while passing through the oh is an idler light or a signal light.

In addition, the present invention in the OPO laser device having a stable output of high efficiency through OPO by using the pump light of the DPSS laser to achieve the above object, the pump light and the reflected polarization of the pump light transmitted and polarized by the polarizing splitter The pump polarized light is passed through the OPO, and the reflected polarized pump light is added to the light passed through the OPO by using two reflective mirrors and an optical splitter to amplify the output of the OPO laser. An opio laser device using two orthogonal polarization pump light sources,

In the OPO laser device having a stable output of high efficiency through OPO by constructing an optical isolator that uses a DPSS laser as a source of the pump light, and protects the DPSS laser from the reflected pump light, between the aforementioned DPSS laser and the optical isolator A polarizing splitter is installed to separate the pump light of DPSS into a transmission polarized pump light and a reflection polarized pump light, and the transmission polarized pump light passes through an OPO, and the reflected polarized pump light uses two reflective mirrors and an optical splitter. An opio laser device using two orthogonal polarization pump light sources, characterized in that it amplifies the output of an OPO laser in addition to the light that has passed through it,

In the intra-cavity OPO laser device in which the OPO is added inside the DPSS laser and has a stable output with high efficiency, the pump light in the aforementioned DPSS laser is transmitted and polarized by the polarization splitter and the pump light polarized by reflection. Orthogonal two, characterized in that the transmission polarized pump light is passed through the OPO, and the reflected polarized pump light is added to the light passed through the OPO by using two reflecting mirrors and light splitters to amplify the output of the OPO laser Provided is an opio laser apparatus using a polarization pump light source.

Here, a half-wave plate disposed between the reflective mirror and the reflective mirror to match the direction of the pump polarized light with the transmission polarized pump light, and an OPO following the optical splitter. The present invention provides an opio laser apparatus using two orthogonal polarization pump light sources for outputting amplified idler light or signal light by constructing an optical parametric amplifier (OPA) for amplifying light into a reflected polarized pump light.

In this way, the present invention uses both pump lights mixed with light vibrating in two orthogonal directions, thereby minimizing energy loss and outputting lasers having different wavelengths or amplifying the output of the lasers. It has a useful effect.

1 is a general configuration diagram of a conventional high power opio laser device

2 is a block diagram of a first embodiment of an opio laser using two orthogonal polarization pump light sources according to the present invention;

3 is a block diagram of a second embodiment of an opio laser using two orthogonal polarization pump light sources according to the present invention;

4 is a block diagram of a third embodiment of an opio laser using two orthogonal polarization pump light sources according to the present invention;

5 is a block diagram of a fourth embodiment of an opio laser using two orthogonal polarization pump light sources according to the present invention;

6 is a block diagram of a fifth embodiment of an opio laser using two orthogonal polarization pump light sources according to the present invention;

7 is a block diagram of a sixth embodiment of an opio laser using two orthogonal polarization pump light sources according to the present invention;

* Explanation of symbols for the main parts of the drawings

1: DPSS laser 2: OPO 3: optical isolator

10: pump light ( 11: Transmission Polarized Pump Light 12: Reflective Polarized Pump Light

20: polarization splitter (P) 30: reflection mirror 40: half wave plate

50: optical splitter 60: OPA 70: idler optical ( )

80: signal light ( L: lens A: aperture

A.O .: acousto-optic modulator R: Rod & Diode pumping module

Referring to the present invention in more detail with reference to the accompanying drawings as follows.

A first embodiment of an opio laser apparatus using two orthogonal polarization pump light sources according to the invention is shown in FIG. 2.

As can be seen from the above, the present invention provides a stable output of high efficiency through an OPO (2) which operates from a pump light (10) as a source such as a DPSS laser (1) mixed with light vibrating in two orthogonal directions. In the OPO (2) laser device having, each pump light (11, 12) separated from the polarizing splitter (20) for separating the pump light (10) described above into a transmission polarized pump light 11 and a reflective polarized pump light (12) It consists of two incident OPOs 2.

The polarization splitter 20 described above is installed between the pump light 10 and the OPO 2, and transmits the polarized pump light 11 having a wavelength oscillating in a direction parallel to the traveling direction of the pump light 10, and transmits the pump light 10. The polarized pump light 12 having a wavelength oscillating in the direction perpendicular to the traveling direction of the X) functions to reflect, thereby separating the pump light 10 into a transmission polarized pump light 11 and a reflected polarized pump light 12.

The two pump lights 11 and 12 separated in this manner are respectively incident on the OPO 2 and have idler light 70 having different frequencies according to the phase matching conditions of the nonlinear crystals in the respective OPO 2. ) And signal light 80 are generated, and selectively transmits, outputs, reflects and amplifies the idler light 70 and the signal light 80 by M2 and M2 '(output coupler) of the OPO 2. The pump light 11 transmitted through polarized light can be incident to the OPO 2 to output the idler light 70 or the signal light 80 of a desired wavelength, and the reflected polarized pump light 12 is used as the pump light source. By inputting to the other OPO (2) to output the idler light 70 or the signal light 80 of another desired wavelength can be output two OPO (2) lasers having different wavelengths at the same time.

Here, as shown in FIG. 3, a portion or a large amount of the transmitted pump light 10 may be reflected by the OPO 2 according to the resonance condition of the mirror used in the OPO, so that the DPSS is reflected by the pump light 10. Damage to the device generating the pump light 10, such as the laser (1) may occur, in order to prevent the optical to block the pump light 10 is reflected from the OPO (2) in front of the device for generating the pump light 10 The optical isolator 3 can be further configured.

In addition, as shown in FIG. 4, an internal pump light 10 reflected by a known intra-cavity OPO laser device including an OPO 2 in the DPSS laser 1 is used. The third embodiment to which the present invention is applied to simultaneously output two OPO 2 lasers having different wavelengths is shown.

As can be seen from the above, the present invention is separated from the polarization splitter 20 which separates the pump light 10 into the transmission polarized pump light 11 and the reflective polarized pump light 12 inside the DPSS laser 1 described above. Each of the pump lights 11 and 12 is composed of two OPOs 2 incident thereon. As in the first embodiment, the pump-polarized pump light 11 as the pump light source is incident on the OPO 2 to output the idler light 70 or the signal light 80 of a desired wavelength, and at the same time the reflected-polarized pump light 12 Can be used as a pump light source to enter another OPO (2) to output the idler light 70 or signal light (80) of another desired wavelength can be output at the same time heterogeneous OPO (2) laser, In particular, in the case of the OPO operating inside the DPSS laser 1, since the distance until the pump light 10 is incident on the OPO 2 is short, the lens L that collects the light is not necessary and can be miniaturized.

In addition, in the third embodiment, any one of the two polarized pump lights 11 and 12 is incident on the OPO 2 outside the DPSS laser 1 to output the OPO 2 laser. It is a matter of course that the present invention can be applied to a form in which an intra-cavity OPO (2) laser and an extra-cavity OPO (2) laser are mixed.

In addition, FIG. 5 shows a configuration diagram of the fourth embodiment used to amplify the output of the OPO 2 laser by using two separate pump lights 11 and 12.

As can be seen from the above, the present invention is an OPO having a stable output of high efficiency through the OPO (2) as a source of the pump light (10), such as DPSS laser (1) mixed with the light oscillating in two orthogonal directions (2) In the laser device, using the polarizing splitter 20 which separates the above-mentioned pump light 10 into the transmission polarized pump light 11 and the reflection polarized pump light 12, and the reflected polarized pump light 12, Two reflection mirrors 30 and an optical splitter 50 for amplifying the output light output from the OPO 2 to a greater intensity, and pumped light reflected between the reflection mirror 30 and the reflection mirror 30 A half-wave plate 40 which rotates the polarization direction of 12) by 90 ^° to match the polarization direction of the transmission-polarized pump light 11, from the reflective-polarized pump light 12 and the OPO 2 It consists of an OPA 60 that amplifies the output light to be added to a laser of greater intensity.

The above-described polarizing splitter 20 is installed between the pump light 10 and the OPO 2, and the polarizing light vibrates in a direction parallel to the plane (the ground in the drawing) made by the direction of the pump light 10 and the normal of the polarizing splitter surface. The transmitted pump light 11 is transmitted, and the polarized pump light 12 oscillating in the direction perpendicular to the plane made by the traveling direction of the pump light 10 and the normal of the polarizing splitter surface is reflected to transmit the pump light 10. The polarized pump light 11 and the reflected polarized pump light 12 are separated. Of the two pump lights 11 and 12 separated as described above, the transmitted and polarized pump light 11 is incident on the OPO 2, and the reflected polarized pump light 12 reflected by the polarization splitter 20 is reflected to the reflection mirror 30. The light is reflected again and then proceeds in the same direction as the pump light of the transmission-polarized pump light 11 in the same direction as the traveling direction, and then is reflected using the reflection mirror 30 to be added to the light output from the OPO 2, from the OPO 2. The output light transmitted from the reflected polarized pump light 12 and the OPO 2 are reflected in the same straight line by using the light splitter 50 which transmits the output light to be transmitted and the reflected polarized pump light 12 is reflected. So that it is added to the second nonlinear optical gain medium.

At this time, the polarization direction of the reflected polarized pump light 12 and the polarization direction of the transmission pump light for operating the OPO 2 to output signal light or idler light must be identical to satisfy the same nonlinear optical phase matching condition from the OPO 2. Since it is possible to amplify the output light output, the pump polarized pump light 12 before being added to the light output from the OPO 2, that is, the pump light polarized between the reflective mirror 30 and the reflective mirror 30 ( A half wave plate 40 is added to rotate the oscillation direction of 12) by 90 ^° to be in the same direction as the transmission polarized pump light 11.

In this manner, the output light from the pump light 12 and the OPO 2 rotated by the reflective polarized pump light 12 by 90 ^° under conditions satisfying the same nonlinear optical phase matching is OPA (60; second non-linear optical gain medium). When passing simultaneously, the mutual interaction between the pump light 12, the signal light 80 and the idler light 70 occurs through the nonlinear polarization induced in the medium, and ultimately the energy of the pump light 12 is transmitted to the signal light 80 ) And the idler light 70, the intensity of the pump light 12 is reduced while the intensity of the signal light 80 and the idler light 70 is amplified. The amplified output light output from the OPO 2 is then reflected and polarized by the light splitter 50 in front of the OPA 60. It can output a laser.

Here, as shown in FIG. 6, since a portion of the pump light 10 may be reflected by the OPO 2, an apparatus for generating the pump light 10 such as the DPSS laser 1 by the reflected pump light 10. The optical isolator 3 may further be configured to block the pump light 10 reflected and re-incident from the OPO 2 in front of the apparatus for generating the pump light 10 in order to prevent breakage of the pump.

In addition, as shown in FIG. 7, an internal pump light 12 reflected by the known intra-cavity OPO 2 laser device including the OPO 2 inside the DPSS laser 1 and vibrating is reflected. The sixth embodiment to which the present invention is applied to amplify an OPO (2) laser by using a.

As can be seen from the above, the present invention is the polarization splitter 20 and the reflection which separates the pump light 10 into the transmission polarized pump light 11 and the reflective polarized pump light 12 inside the DPSS laser 1 described above. Two reflection mirrors 30 and a light splitter 50 for adding the polarized pump light 12 to the output light output from the OPO 2, and the reflection polarization between the reflection mirror 30 and the reflection mirror 30. To amplify the half wave plate 40 which matches the direction of the wavelength of the pump light 12 with the transmission polarized pump light 11, and the laser to which the output light output from the reflected polarized pump light 12 and the OPO 2 is added. It consists of an OPA 60. In this embodiment, as in the fourth embodiment, the reflective polarized pump light 12 separated inside the DPSS laser 1 is passed through the half wave plate 40 so that the oscillation direction is coincided with the transmission polarized pump light 11. The reflection mirror 30 and the optical splitter 50 can be used to amplify the output light output from the OPO 2 by passing the OPA 60 in addition to the light output from the OPO 2, and the pump light 10. Since the distance to the incident to the OPO 2 is short, the lens L that collects light is no longer necessary and can be miniaturized.

Further, in the sixth embodiment, the reflected polarized pump light 12 is incident on the OPO 2, and the transmitted polarized pump light 11 is caused to vibrate in the same direction as the reflected polarized pump light 12 and then the OPO 2 is removed from the OPO 2. Opio laser devices using two orthogonal polarization pump light sources that amplify in addition to the output light are also included in the present invention.

Claims (14)

In the OPO laser device having a stable output of high efficiency through OPO by using the pump light of the DPSS laser, The above-mentioned pump light is separated into a pump light polarized by a polarization splitter and a pump light polarized by a polarization splitter, and each of the pump light beams used as a source has a different wavelength desired through an OPO satisfying a nonlinear optical phase matching condition of a different condition. Opio laser device using two orthogonal polarization pump light source, characterized in that to output two OPO laser at the same time. An OPO laser apparatus having a stable output of high efficiency through OPO by constructing an optical isolator that uses a DPSS laser as a source of pump light and protects the DPSS laser from reflected pump light, A polarization splitter is provided between the DPSS laser and the optical isolator to separate the pump light of the DPSS into a transmission polarized pump light and a reflective polarized pump light, and to satisfy different nonlinear optical phase matching conditions by using each separated pump light as a source. An opio laser apparatus using two orthogonal polarized pump light sources, characterized in that an OPO is operated to simultaneously output an OPO laser having two different wavelengths as desired. In the intra-cavity OPO laser device having a stable output of high efficiency by adding OPO inside the DPSS laser, The above-mentioned pump light inside the DPSS laser resonator is separated into a pump light polarized by a polarization splitter and a pump light polarized by a polarization splitter, and each desired pump light is used as a source to satisfy a different nonlinear optical phase matching condition. Opio laser device using two orthogonal polarized pump light source, characterized in that to output two OPO laser at the same time. The method according to claim 1 to 3, An opio laser apparatus using two orthogonal polarization pump light sources, characterized in that a reflection mirror is installed after the polarization splitter so that the reflective polarization pump light reflected from the aforementioned polarization splitter is propagated in the same direction as the transmission polarization pump light. The method according to claim 1 to 3, The opio laser device using two orthogonal polarization pump light sources, characterized in that the two OPO lasers are output at the same time is an idler (Idler) light. The method according to claim 1 to 3, The opio laser device using two orthogonal polarized pump light sources, characterized in that the two OPO lasers are output at the same time is a signal light. The method according to claim 1 to 3, The opio laser device using two orthogonal polarization pump light sources, characterized in that the two OPO lasers are simultaneously output is an idler light and a signal light. In the OPO laser device having a stable output of high efficiency through OPO by using the pump light of the DPSS laser, The above-mentioned pump light is separated into a pump light polarized by a polarization splitter and a pump light polarized by a polarization splitter. The pump polarized pump light is incident on an OPO, and the reflected polarized pump light is OPO using two reflective mirrors and an optical splitter. Opio laser device using two orthogonal polarization pump light source, characterized in that the amplification of the output of the OPO laser in addition to the light output from the. An OPO laser apparatus having a stable output of high efficiency through OPO by constructing an optical isolator that uses a DPSS laser as a source of pump light and protects the DPSS laser from reflected pump light, A polarization splitter is provided between the DPSS laser and the optical isolator to separate the pump light of the DPSS into a transmission polarized pump light and a reflective polarized pump light, and the transmitted polarized pump light is incident on an OPO, and the reflective polarized pump light is provided by two reflective mirrors. And an opio-laser device using two orthogonal polarization pump light sources, characterized in that it amplifies the output of the OPO laser in addition to the light output from the OPO using an optical splitter. In the intra cavity OPO laser device having a stable output of high efficiency by adding OPO inside the DPSS laser, The pump light inside the DPSS laser is separated into a pump light polarized by a polarization splitter and a pump light polarized by a polarization splitter. The pump polarized pump light is incident on an OPO, and the pump light polarized by the polarization splitter uses two reflective mirrors and a light splitter. Opio laser device using two orthogonal polarization pump light source, characterized in that the amplification of the output of the OPO laser in addition to the light output from the OPO. The method according to claim 8 to 10, Two orthogonal polarization pump light sources are installed between the reflection mirror and the reflection mirror to install a half-wave plate for matching the vibration direction of the reflected polarized pump light with the vibration direction of the transmitted polarized pump light. Used opio laser device. The method according to claim 8 to 10, An opio laser apparatus using two orthogonal polarized pump light sources, characterized in that it comprises an OPA that amplifies the light passing through the OPO following the above-described optical splitter into the reflected polarized pump light. The method according to claim 8 to 10, Opio laser device using two orthogonal polarization pump light source, characterized in that the light passing through the above-mentioned OPO is an idler light. The method according to claim 8 to 10, Opio laser device using two orthogonal polarization pump light source, characterized in that the light passing through the above-described OPO is a signal (Signal).