CN105490154A - Medical 673nm and 1064nm dual-wavelength fiber output laser device - Google Patents
Medical 673nm and 1064nm dual-wavelength fiber output laser device Download PDFInfo
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- CN105490154A CN105490154A CN201410530988.2A CN201410530988A CN105490154A CN 105490154 A CN105490154 A CN 105490154A CN 201410530988 A CN201410530988 A CN 201410530988A CN 105490154 A CN105490154 A CN 105490154A
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Abstract
The invention provides a medical 673nm and 1064nm dual-wavelength fiber output laser device. A 1064nm beam-splitting fiber coil is arranged at the tail segment of a 1064nm laser output fiber to split one path of 1064nm laser output; a 673nm signal beam, a 750nm idler beam, a 1064nm pump beam I and a 532nm pump beam II enter the 673nm four-wave mixing periodically poled lithium niobate laser resonator cavity to generate a four-wave mixing effect; a 673nm signal beam output is generated; and a 673nm and 1064nm dual-wavelength fiber output is finally output.
Description
Technical field: laser and applied technical field.
Technical background:
673nm, 1064nm dual-wavelength laser, the laser applied for medical spectral detection, lasing light emitter, instrumental analysis etc., it can be used as medical optical fiber and passes the using light sources such as the analyzing and testing of 673nm, 1064nm dual wavelength sensor, and it is also for the laser such as medical optical communication and optoelectronic areas; Fiber laser is as the representative of third generation laser technology, and having mercy on property, the glass material with glass optical fiber low cost of manufacture and optical fiber have extremely low bulk area ratio, and rapid heat dissipation, loss are low with conversion efficiency comparatively advantages of higher, and range of application constantly expands.
Summary of the invention:
A kind of medical 673nm, 1064nm dual-wavelength optical-fiber output laser, at 1064nm Laser output optical fiber rear, 1064nm splitting optical fiber circle is set, beam splitting one road 1064nm Laser output, flashlight 673nm, ideler frequency light 750nm, pump light I1064nm and pump light II532nm enter 673nm four wave mixing periodically poled lithium niobate laserresonator, there is four-wave mixing effect, produce flashlight 673nm to export, finally export 673nm, 1064nm dual-wavelength optical-fiber Laser output.
Scheme one, 673nm tetra-long wavelength fiber laser structure.
There is the structure of the periodically poled lithium niobate laserresonator 38 of four wave mixing in signalization light 673nm, ideler frequency light 750nm, pump light I1064nm and pump light II532nm, arranges 673nm focus on output coupling mirror coupling access 673nm output optical fibre at 673nm four wave mixing periodically poled lithium niobate laserresonator output.
Scheme two, 1064nm laser beam splitter fiber turns is set
Arrange 1064nm splitting optical fiber circle at 1064nm Laser output optical fiber rear, beam splitting one road 1064nm laser exports through 1064nm laser output.
Scheme three, 750nm periodically poled lithium niobate laser parameter oscillating tank chamber is set
750nm periodically poled lithium niobate laser parameter oscillating tank chamber is set, set gradually from its input: the 750nm of 3-stage optical fiber input mirror, 1064nm parametric oscillation basic frequency laser crystal, parametric oscillation input mirror, 1500nm periodically poled lithium niobate laser crystal, 1500nm outgoing mirror, 750nm frequency-doubling crystal and output focuses on output coupling mirror, forms 750nm periodically poled lithium niobate laser parameter oscillating tank chamber thus.
Scheme four, 532nm frequency multiplication resonant cavity is set
532nm frequency multiplication resonant cavity is set, sets gradually from its input: secondary input mirror, 1064nm basic frequency laser crystal, 532nm frequency-doubling crystal, 532nm outgoing mirror 21 focus on output coupling mirror with the 532nm of output, form 532nm frequency multiplication resonant cavity thus.
Scheme five, 1064nm resonant cavity is set
1064nm resonant cavity is set, 1064nm resonant cavity is set, set gradually from its input: the 1064nm of one-level input mirror, 1064nm laser crystal, 1064nm outgoing mirror and output focuses on output coupling mirror, forms 1064nm resonant cavity thus.
Scheme six, 3-stage optical fiber structure is set
3-stage optical fiber structure is set, 3-stage optical fiber structure is integrally connected by one-level fiber turns, secondary fiber turns and 3-stage optical fiber circle and forms, one-level fiber turns is connected on semiconductor module by 808nm pumping coupler, semiconductor module is by semiconductor module Power supply, above-mentioned whole optical element is all arranged on optical rail and ray machine tool, and optical rail and ray machine tool arrange fan 3.
Scheme five, the course of work
Semiconductor module Power supply is powered to semiconductor module, semiconductor module is launched 808nm laser and is coupled into one-level fiber turns through 808nm pumping coupler, thus enter secondary fiber turns and the 3-stage optical fiber circle of 3-stage optical fiber structure, 808nm laser obtains gain in 3-stage optical fiber structure, 3-stage optical fiber output is drawn from by 3-stage optical fiber circle, input 808nm laser enters 750nm periodically poled lithium niobate laser parameter oscillating tank chamber, the 1064nm laser that 1064nm parametric oscillation basic frequency laser crystal through 750nm periodically poled lithium niobate laser parameter oscillating tank chamber generates goes pump optical parametric oscillation to generate 1500nm laser, enter 750nm frequency-doubling crystal frequency multiplication through 1500nm outgoing mirror and export 750nm laser, focus on output coupling mirror through 750nm to export, form 750nm periodically poled lithium niobate laser parameter oscillating tank chamber thus., focusing on output coupling mirror through 750nm is coupled in 750nm output optical fibre, by its input 750nm laser in dual wavelength parameter coupler, secondary fiber-optic output is drawn from by secondary fiber turns, input 808nm laser enters 532nm frequency multiplication resonant cavity, 1064nm basic frequency laser crystal through 532nm frequency multiplication resonant cavity generates 1064nm fundamental frequency and exports 532nm laser through 532nm frequency multiplication resonant cavity generation frequency multiplication, focusing on output coupling mirror through 532nm is coupled in 532nm output optical fibre, by its input 532nm laser in dual wavelength parameter coupler, one-level fiber-optic output is drawn from by one-level fiber turns, input 808nm laser enters 1064nm resonant cavity, 1064nm resonant cavity generates 1064nm basic frequency laser, focuses on output coupling mirror be coupled in 1064nm output optical fibre through 1064nm, by its input 1064nm laser in dual wavelength parameter coupler, thus, 750nm laser, 1064nm laser and 532nm laser are coupled into 673nm four wave mixing periodically poled lithium niobate laserresonator through dual wavelength parameter coupler, flashlight 673nm, ideler frequency light 750nm, there is four-wave mixing effect in pump light I1064nm and pump light II532nm, flashlight 673nm is occurred, gain, flashlight 673nm focuses on output coupling mirror through 673nm and is coupled to 673nm output optical fibre, export 673nm Laser output, at 1064nm Laser output optical fiber rear, 1064nm splitting optical fiber circle is set, beam splitting one road 1064nm laser exports through 1064nm laser output, finally export 673nm, 1064nm dual-wavelength optical-fiber Laser output.
Core content of the present invention:
A kind of medical 673nm, 1064nm dual-wavelength optical-fiber output laser, at 1064nm Laser output optical fiber rear, 1064nm splitting optical fiber circle is set, beam splitting one road 1064nm laser exports through 1064nm laser output, there is the structure of the periodically poled lithium niobate laserresonator of four wave mixing in signalization light 673nm, ideler frequency light 750nm, pump light I1064nm and pump light II532nm, four wave mixing generates 673nm optical-fiber laser and exports, and forms 673nm, 1064nm dual-wavelength optical-fiber output laser structure.
1064nm splitting optical fiber circle beam splitting one road 1064nm Laser output, flashlight 673nm, ideler frequency light 750nm, pump light I1064nm and pump light II532nm enter 673nm four wave mixing periodically poled lithium niobate laserresonator, there is four-wave mixing effect, generate flashlight 673nm Laser output, form 673nm, 1064nm dual-wavelength optical-fiber Laser output.
Accompanying drawing illustrates:
Accompanying drawing is the structure chart of this patent, and accompanying drawing is wherein: 1, optical rail and ray machine tool, 2, semiconductor module, 3, fan, 4, 808nm pumping coupler, 5, semiconductor module block power supply, 6, one-level fiber turns, 7, one-level fiber-optic output, 8, one-level fiber coupler, 9, one-level input mirror, 10, 1064nm laser crystal, 11, 1064nm outgoing mirror, 12, focus on output coupling mirror, 13, 1064nm output optical fibre, 14, 1064nm resonant cavity, 15, secondary fiber turns, 16, secondary fiber-optic output, 17, secondary fiber coupler, 18, 532nm focuses on output coupling mirror, and 19, 532nm output optical fibre, 20, 532nm frequency-doubling crystal, 21, 532nm outgoing mirror, 22, 1064nm basic frequency laser crystal, 23, secondary input mirror, 24, 532nm frequency multiplication resonant cavity, 25, 3-stage optical fiber circle, 26, 750nm output optical fibre, 27, 750nm focuses on output coupling mirror, and 28, 750nm outgoing mirror, 29, 1500nm periodically poled lithium niobate laser crystal, 30, parametric oscillation input mirror, 31, 1064nm parametric oscillation basic frequency laser crystal, 32, 3-stage optical fiber input mirror, 33, dual wavelength parameter coupler, 34, 3-stage optical fiber coupler, 35, 750nm periodically poled lithium niobate laser parameter oscillating tank chamber, 36, 3-stage optical fiber output, 37, dual wavelength parameter coupling transmission optical fiber, 38, 673nm four wave mixing periodically poled lithium niobate laserresonator, 39, dual wavelength input mirror, 40, 673nm four wave mixing periodically poled lithium niobate laser crystal, 41, 673nm outgoing mirror, 42, 673nm focuses on output coupling mirror, and 43, 673nm output optical fibre, 44, 673nm Laser output, 45, 1064nm Laser output optical fiber, 46, 1064nm splitting optical fiber circle, 47, 3-stage optical fiber structure, 48, 750nm frequency-doubling crystal.
Embodiment:
673nm four wave mixing periodically poled lithium niobate laserresonator 38 is set, 750nm splitting optical fiber circle 48 is set, 1064nm splitting optical fiber circle is set, arrange, signalization light 673nm, ideler frequency light 750nm, there is the structure of the periodically poled lithium niobate laserresonator 38 of four wave mixing in pump light I1064nm and pump light II532nm, 673nm is set at 673nm four wave mixing periodically poled lithium niobate laserresonator 38 output and focuses on output coupling mirror 42 coupling access 673nm output optical fibre 43, at the rear of 1064nm output optical fibre 13,1064nm splitting optical fiber circle 46 is set, the 1064nm laser output 45 of 1064nm splitting optical fiber circle 46 is set, ideler frequency light 750nm, pump light I1064nm and pump light II532nm with derive from dual wavelength parameter coupling transmission optical fiber 37, dual wavelength parameter coupler 33 is set before dual wavelength parameter coupling transmission optical fiber 37, by 1064nm output optical fibre 13, 532nm output optical fibre 19 is coupled with 750nm output optical fibre 26 and accesses dual wavelength parameter coupler 33, 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35 is set, 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35 focuses on output coupling mirror 27 by the 750nm of its output and is linked in 750nm output optical fibre 26, the input in 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35 is connected on 3-stage optical fiber output 36 by 3-stage optical fiber coupler 34, 3-stage optical fiber output 36 is drawn by the 3-stage optical fiber circle 25 of 3-stage optical fiber structure 47, 532nm frequency multiplication resonant cavity 24 is set, 532nm frequency multiplication resonant cavity 24 focuses on output coupling mirror 18 by the 532nm of its output and is linked in 532nm output optical fibre 19,532nm frequency multiplication resonant cavity 24 is connected on secondary fiber-optic output 16 by the secondary fiber coupler 17 of its input, and secondary fiber-optic output 16 is drawn from the secondary fiber turns 15 of 3-stage optical fiber structure 47, 1064nm resonant cavity 14 is set, the output of 1064nm resonant cavity 14 focuses on output coupling mirror 12 by 1064nm and is linked in 1064nm output optical fibre 13,1064nm resonant cavity 14 is connected on one-level fiber-optic output 7 by the one-level fiber coupler 8 of its input, and one-level fiber-optic output 7 is drawn by the one-level fiber turns 6 of 3-stage optical fiber structure 47, 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35 is set, set gradually from its input: the 750nm of 3-stage optical fiber input mirror 32,1064nm parametric oscillation basic frequency laser crystal 31, parametric oscillation input mirror 30,1500nm periodically poled lithium niobate laser crystal 29,1500nm outgoing mirror 28,750nm frequency-doubling crystal 48, output focuses on output coupling mirror 27, forms 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35 thus, 532nm frequency multiplication resonant cavity 24 is set, set gradually from its input: secondary input mirror 23,1064nm basic frequency laser crystal 22,532nm frequency-doubling crystal 20,532nm outgoing mirror 21 focus on output coupling mirror 18 with the 532nm of output, form 532nm frequency multiplication resonant cavity 24 thus, 1064nm resonant cavity 14 is set, set gradually from its input: one-level input mirror 9, 1064nm laser crystal 10, 1064nm outgoing mirror 11 focuses on output coupling mirror 12 with the 1064nm of output, form 1064nm resonant cavity 14 thus, 3-stage optical fiber structure 47 is set, 3-stage optical fiber structure 47 is by one-level fiber turns 6, secondary fiber turns 15 and 3-stage optical fiber circle 25 are integrally connected and form, one-level fiber turns 6 is connected on semiconductor module 2 by 808nm pumping coupler 4, semiconductor module 2 is powered by semiconductor module block power supply 5, above-mentioned whole optical element is all arranged on optical rail and ray machine tool 1, optical rail and ray machine tool 1 arrange fan 3, overall formation 673nm, 1064nm dual-wavelength optical-fiber output laser structure.
The course of work:
Semiconductor module block power supply 5 is powered and to be powered to semiconductor module 2, semiconductor module 2 is launched 808nm laser and is coupled into one-level fiber turns 6 through 808nm pumping coupler 4, thus enter secondary fiber turns 15 and the 3-stage optical fiber circle 25 of 3-stage optical fiber structure 47, 808nm laser obtains gain in 3-stage optical fiber structure 47, 3-stage optical fiber output 36 is drawn from by 3-stage optical fiber circle 25, input 808nm laser enters 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35, the 1064nm laser that 1064nm parametric oscillation basic frequency laser crystal 31 through 750nm periodically poled lithium niobate laser parameter oscillating tank chamber 35 generates goes pump optical parametric oscillation to generate 1500nm laser, 750nm laser is exported through 750nm frequency-doubling crystal 48 frequency multiplication, focusing on output coupling mirror 27 through 750nm is coupled in 750nm output optical fibre 26, by its input 750nm laser in dual wavelength parameter coupler 33, secondary fiber-optic output 16 is drawn from by secondary fiber turns 15, input 808nm laser enters 532nm frequency multiplication resonant cavity 24,1064nm basic frequency laser crystal 22 through 532nm frequency multiplication resonant cavity 24 generates 1064nm fundamental frequency, through 532nm frequency multiplication resonant cavity 24, frequency multiplication output 532nm laser occurs, focusing on output coupling mirror 18 through 532nm is coupled in 532nm output optical fibre 19, by its input 532nm laser in dual wavelength parameter coupler 33, one-level fiber-optic output 7 is drawn from by one-level fiber turns 6, input 808nm laser enters 1064nm resonant cavity 14,1064nm resonant cavity 14 generates 1064nm basic frequency laser, focusing on output coupling mirror 12 through 1064nm is coupled in 1064nm output optical fibre 13, by its input 1064nm laser in dual wavelength parameter coupler 33, thus, 750nm laser, 1064nm laser and 532nm laser are coupled into 673nm four wave mixing periodically poled lithium niobate laserresonator 38 through dual wavelength parameter coupler 33, flashlight 673nm, ideler frequency light 750nm, there is four-wave mixing effect in pump light I1064nm and pump light II532nm, flashlight 673nm is occurred, gain, flashlight 673nm focuses on output coupling mirror 42 through 673nm and exports 673nm Laser output 44 with 673nm output optical fibre 43, 1064nm splitting optical fiber circle 47 beam splitting arranged at the rear of 1064nm output optical fibre 13 exports 1064nm laser, 1064nm is exported through output 45.
Claims (2)
1. medical 673nm, 1064nm dual-wavelength optical-fiber output laser, it is characterized by, at 1064nm Laser output optical fiber rear, 1064nm splitting optical fiber circle is set, beam splitting one road 1064nm laser exports through 1064nm laser output, there is the structure of the periodically poled lithium niobate laserresonator of four wave mixing in signalization light 673nm, ideler frequency light 750nm, pump light I1064nm and pump light II532nm, four wave mixing generates 673nm optical-fiber laser and exports, and forms 673nm, 1064nm dual-wavelength optical-fiber output laser structure.
2. one according to claim 1 medical 673nm, 1064nm dual-wavelength optical-fiber output laser, it is characterized by, 1064nm splitting optical fiber circle beam splitting one road 1064nm Laser output, flashlight 673nm, ideler frequency light 750nm, pump light I1064nm and pump light II532nm enter 673nm four wave mixing periodically poled lithium niobate laserresonator, there is four-wave mixing effect, generate flashlight 673nm Laser output, form 673nm, 1064nm dual-wavelength optical-fiber Laser output.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201410530988.2A CN105490154A (en) | 2014-10-09 | 2014-10-09 | Medical 673nm and 1064nm dual-wavelength fiber output laser device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201410530988.2A CN105490154A (en) | 2014-10-09 | 2014-10-09 | Medical 673nm and 1064nm dual-wavelength fiber output laser device |
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| Publication Number | Publication Date |
|---|---|
| CN105490154A true CN105490154A (en) | 2016-04-13 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201410530988.2A Pending CN105490154A (en) | 2014-10-09 | 2014-10-09 | Medical 673nm and 1064nm dual-wavelength fiber output laser device |
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| CN (1) | CN105490154A (en) |
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- 2014-10-09 CN CN201410530988.2A patent/CN105490154A/en active Pending
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Application publication date: 20160413 |