CN204651672U - Based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping - Google Patents

Abstract

A kind of based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, comprise superfluorescence seed light source, Pre-power amplifier and same band draw power main amplifier, superfluorescence seed light source comprises the first residue pumping light decanter, first side pump bundling device, first multimode optically pumped laser, first Double Cladding Ytterbium Doped Fiber, second side pump bundling device, second residue pumping light decanter, first fibre optic isolater, second fibre optic isolater, Pre-power amplifier comprises the first (N+1) × 1 optical fiber pumping signal bundling device, second multimode optically pumped laser, second Double Cladding Ytterbium Doped Fiber, 3rd residue pumping light decanter, 3rd fibre optic isolater, the second (N+1) × 1 optical fiber pumping signal bundling device is comprised with band draw power main amplifier, with being with PLM, 3rd Double Cladding Ytterbium Doped Fiber, 3rd (N+1) × 1 backward pump signal bundling device, 4th residue pumping light decanter and fiber-optic output cap.It achieves high brightness superfluorescent fiber sources and exports.

Description

Based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping

Technical field

The utility model relates to laser technology field, particularly a kind of based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping.

Background technology

Fiber laser has that conversion efficiency is high, good beam quality, compact conformation, the advantage such as easy to maintenance, have a wide range of applications in the field such as scientific research, industrial processes.Current high-capacity optical fiber laser adopts the MOPA structure with multistage amplifier chain mostly, and seed source is semiconductor laser or vibration cavity configuration fiber laser.Because semiconductor laser and vibration cavity configuration fiber laser export, there is relaxation oscillation characteristic, and there is weak locked mode phenomenon, cause the pulse easily occurring high-peak power in high power amplification process, the nonlinear effects such as stimulated Raman scattering are very easily produced, the unrepairable of optical fiber may be brought to damage, even produce " optics electric discharge ", cause heavy losses.

Superfluorescence is the transition state between laser and fluorescence, amplified spont-aneous emission (ASE), there is the features such as spectral coverage is wide, temporal coherence is low, temperature stability is strong, in fields such as optical tomography, high-precision optical fiber gyro sensing, optical fiber communications, there is extensive use.In addition, super-fluorescence light source, compared with laser, also has non-mode competition, without relaxation oscillation, without outstanding features such as weak locked mode, high time-domain stability.Rare-earth doped optical fibre is utilized to build all-fiber MOPA structure superfluorescent fiber sources, high-power output can be realized, and have the advantage of fiber laser and super-fluorescence light source concurrently, be the alternatives of novel high-luminance light fibre source, in fields such as industrial processes, there is huge application potential.

At present, high power superfluorescent fiber sources mainly adopts semiconductor laser pumped rare-earth doped optical fibre to realize superfluorescent generation and amplification, there is the drawback (XiangPeng such as serious thermal effect and nonlinear effect, Liang Dong.Temperature Dependence of Ytterbium-doped Fiber Amplifiers [J] .J.Opt.Soc.Am.B, 2008,25 (1): 126 ~ 130; Nathan A.Brilliant, Kalliroi Lagonik.Thermal Effects in a Dual-clad Yetterbium Fiber Laser [J] .OPT.Lett, 2001,26 (21): 1669 ~ 1671).In addition, the limited brightness in existing diode pumped source, continue to improve comparatively difficulty (C.A.Codemard, J.Nilsson, and J.K.Sahu.Tandem Pumping of Large-coreDouble-clad Ytterbium-doped Fiber for Control of Excess Gain [C] .Advanced SolidState Photonics, 2010OSA Technical Digest Series:paper.AWA3).

Utility model content

The purpose of this utility model is to break through diode pumped source luminance shortage to the restriction of superfluorescent fiber sources power output, provides a kind of based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping.

For solving the problems of the technologies described above, the technical solution adopted in the utility model is:

Based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, comprise superfluorescence seed light source, Pre-power amplifier and same band draw power main amplifier.

Wherein, superfluorescence seed light source provides low-power seed source for high power MOPA system; Pre-power amplifier to be used for low-power superfluorescence seed pre-amplification, to suitable power level, avoiding the damage that main amplifying stage brings because seed power is not enough; Utilize the same band PLM of high brightness to carry out plus and blowup to the seed light after pre-amplification with band draw power main amplifier, realize high power superfluorescence and export.

Described superfluorescence seed light source is a kind of Yb dosed optical fiber amplified spontaneous emission source, it comprises the first residue pumping light decanter, first side pump bundling device (combiner), first multimode optically pumped laser, first Double Cladding Ytterbium Doped Fiber, second side pump bundling device, second residue pumping light decanter, first fibre optic isolater, second fibre optic isolater, output end-grain cutting 8 ° of oblique angles of first residue pumping light decanter are to export monitoring ASE, input is connected with the signal fibre of the first side pump bundling device, every root pumping light of the first side pump bundling device injects fibre and is connected with 1 the first multimode optically pumped laser respectively, the output fibre of the first side pump bundling device is connected with one end of the first Double Cladding Ytterbium Doped Fiber, the other end of the first Double Cladding Ytterbium Doped Fiber is connected with the output of the second side pump bundling device, every root pumping light of the second side pump bundling device injects fibre and is connected with 1 the first multimode optically pumped laser respectively, the signal fibre of the second side pump bundling device connects one end of the second residue pumping light decanter, the other end of the second residue pumping light decanter is connected with the input of the first fibre optic isolater, the output of the first fibre optic isolater is connected with the input of the second fibre optic isolater.

Described Pre-power amplifier comprises the first (N+1) × 1 optical fiber pumping signal bundling device (combiner), second multimode optically pumped laser, second Double Cladding Ytterbium Doped Fiber, 3rd residue pumping light decanter, 3rd fibre optic isolater, the signal fibre of output and first (N+1) × 1 optical fiber pumping signal bundling device of the second fibre optic isolater is connected, the N root pumping light of the first (N+1) × 1 optical fiber pumping signal bundling device injects fibre and is connected with 1 the second multimode optically pumped laser respectively, the output fibre of the first (N+1) × 1 optical fiber pumping signal bundling device is connected with one end of the second Double Cladding Ytterbium Doped Fiber, the input that the other end and the 3rd of the second Double Cladding Ytterbium Doped Fiber remains pumping light decanter is connected, the output of the 3rd residue pumping light decanter connects the input of the 3rd fibre optic isolater.

Described same band draw power main amplifier comprises the second (N+1) × 1 optical fiber pumping signal bundling device, with being with PLM, 3rd Double Cladding Ytterbium Doped Fiber, 3rd (N+1) × 1 backward pump signal bundling device, 4th residue pumping light decanter and fiber-optic output cap, the output of the 3rd fibre optic isolater connects the signal fibre of the second (N+1) × 1 optical fiber pumping signal bundling device, the N root pumping light injection fibre of the second (N+1) × 1 optical fiber pumping signal bundling device is same with 1 group is respectively with PLM to be connected, the output fibre of the second (N+1) × 1 optical fiber pumping signal bundling device is connected with one end of the 3rd Double Cladding Ytterbium Doped Fiber, the other end of the 3rd Double Cladding Ytterbium Doped Fiber is connected with the output fibre of the 3rd (N+1) × 1 backward pump signal bundling device, the N root pumping light injection fibre of the 3rd (N+1) × 1 backward pump signal bundling device is same with 1 group is respectively with PLM to be connected, the signal fibre of the 3rd (N+1) × 1 backward pump signal bundling device is connected with the 4th input remaining pumping light decanter, the output of the 4th residue pumping light decanter is connected with the input of fiber-optic output cap.

In the utility model:

The first described multimode optically pumped laser and the centre wavelength of the second multimode optically pumped laser are λ 1,800nm≤λ 1≤1000nm.

The first described Double Cladding Ytterbium Doped Fiber is monomode fiber or multimode large core fiber, and the second Double Cladding Ytterbium Doped Fiber and the 3rd Double Cladding Ytterbium Doped Fiber are multimode large core fiber.

The first described residue pumping light decanter and the second residue pumping light decanter are monomode fiber or the multimode large core fiber of mixing germanium, and its numerical aperture and physical dimension are mated with the first side pump bundling device, the second side pump bundling device respectively.3rd residue pumping light decanter and the 4th residue pumping light decanter are the multimode large core fiber mixing germanium, and its numerical aperture and physical dimension are mated with the second Double Cladding Ytterbium Doped Fiber, the 3rd Double Cladding Ytterbium Doped Fiber respectively.

The model that the first described fibre optic isolater, the tail optical fiber type of the second fibre optic isolater and second remain pumping light decanter tail optical fiber is identical, bear power and be not less than 50W, anti-reflection within the scope of 1050 ~ 1150nm, introduce feedback to avoid isolator and cause superfluorescence seed source self excitation threshold to reduce.The model that the fiber type and the 3rd of the 3rd fibre optic isolater remains pumping light decanter tail optical fiber is identical, bears power and is not less than 150W, anti-reflection within the scope of 1050 ~ 1150nm.

The model of the first described (N+1) × 1 optical fiber pumping signal bundling device, the signal fibre of the second (N+1) × 1 optical fiber pumping signal bundling device is identical with the tail optical fiber model of the second fibre optic isolater, the 3rd fibre optic isolater respectively, and the signal of the 3rd (N+1) × 1 backward pump signal bundling device is fine, export fine physical dimension with the 3rd Double Cladding Ytterbium Doped Fiber, numerical aperture is identical.All the pumping light injection end of (N+1) × 1 optical fiber pumping signal bundling device is N number of, 1≤N≤200.

Described same band PLM, its centre wavelength is λ ₂, 1000nm≤λ ₂≤ 1040nm, exemplary operation wavelength is 1018nm.Each with being with PLM to form by 7 number hectowatt grade oscillators and 7 × 1 pumping combiner devices.

The tail optical fiber model that the tail optical fiber model and the 4th of described optical fiber end cap remains pumping light decanter is identical, anti-reflection within the scope of 1050 ~ 1150nm.

Compared with prior art, the utility model has the advantage of:

1, can overcome the restriction that semiconductor pump laser device luminance shortage exports high power superfluorescent fiber sources system, realize high light beam quality, high brightness super-fluorescence light source exports, this system possesses myriawatt fan-out capability.

2, high power all-fiber MOPA structure superfluorescent fiber sources, had both had the stability of all optical fibre structure, and the nothing again with super-fluorescence light source, from the feature of pulse, high time-domain stability, has important application potentiality in the field such as scientific research, industrial processes.

3, the utility model adopts semiconductor pump laser device to carry out pumping to Yb dosed optical fiber in seed source, prime amplifier, adopt in main amplifier, with band PLM, pumping is carried out to large core diameter Yb dosed optical fiber, significantly can reduce system cost under the prerequisite realizing high-power output.

Accompanying drawing explanation

Fig. 1 is that embodiment 1 one kinds is based on the high power all-fiber MOPA structure superfluorescent fiber sources principle schematic with band pumping.

In figure: superfluorescence seed light source 1, Pre-power amplifier 2, with band draw power main amplifier 3, first residue pumping light decanter 11, first side pump bundling device 12, first multimode optically pumped laser 13, first Double Cladding Ytterbium Doped Fiber 14, second side pump bundling device 15, second residue pumping light decanter 16, first fibre optic isolater 17, second fibre optic isolater 18, first (N+1) × 1 optical fiber pumping signal bundling device 21, second multimode optically pumped laser 22, second Double Cladding Ytterbium Doped Fiber 23, 3rd residue pumping light decanter 24, 3rd fibre optic isolater 25, second (N+1) × 1 optical fiber pumping signal bundling device 31, with band PLM 32, 3rd Double Cladding Ytterbium Doped Fiber 33, 3rd (N+1) × 1 backward pump signal bundling device 34, 4th residue pumping light decanter 35, fiber-optic output cap 36.

Embodiment

Below in conjunction with Figure of description and concrete preferred embodiment, the utility model is further described, but does not therefore limit protection range of the present utility model.

Embodiment 1:

Adopt a structure as shown in Figure 1 based on the high power all-fiber MOPA structure super-fluorescence light source with band pumping, mainly comprise three parts such as superfluorescence seed light source 1, Pre-power amplifier 2, same band draw power main amplifier 3.Wherein, superfluorescence seed light source 1 provides low-power seed source for high power MOPA system; Pre-power amplifier 2 for by low-power superfluorescence seed pre-amplification to suitable power level, avoid main amplifying stage because of the damage that brings of seed power deficiency; Utilize the same band PLM of high brightness to carry out plus and blowup to the seed light after pre-amplification with band draw power main amplifier 3, realize high power superfluorescence and export.

Wherein: superfluorescence seed light source 1 is a kind of Yb dosed optical fiber amplified spontaneous emission source, it comprises the first residue pumping light decanter 11, first side pump bundling device (combiner) 12, first multimode optically pumped laser 13, first Double Cladding Ytterbium Doped Fiber 14, second side pump bundling device 15, second residue pumping light decanter 16, first fibre optic isolater 17, second fibre optic isolater 18, output end-grain cutting 8 ° of oblique angles of first residue pumping light decanter 11 are to export monitoring ASE, input is connected with the signal fibre of the first side pump bundling device 12, every root pumping light of the first side pump bundling device 12 injects fibre and is connected with 1 the first multimode optically pumped laser 13 respectively, the output fibre of the first side pump bundling device 12 is connected with one end of the first Double Cladding Ytterbium Doped Fiber 14, the other end of the first Double Cladding Ytterbium Doped Fiber 14 is connected with the output of the second side pump bundling device 15, every root pumping light of the second side pump bundling device 15 injects fibre and is connected with 1 the first multimode optically pumped laser 13 respectively, the signal fibre of the second side pump bundling device 15 connects one end of the second residue pumping light decanter 16, the other end of the second residue pumping light decanter 16 is connected with the input of the first fibre optic isolater 17, the output of the first fibre optic isolater 17 is connected with the input of the second fibre optic isolater 18.

Pre-power amplifier 2 comprises: the first (N+1) × 1 optical fiber pumping signal bundling device (combiner) 21, second multimode optically pumped laser 22, second Double Cladding Ytterbium Doped Fiber 23, 3rd residue pumping light decanter 24, 3rd fibre optic isolater 25, the signal fibre of output and first (N+1) × 1 optical fiber pumping signal bundling device 21 of the second fibre optic isolater 18 is connected, the N root pumping light of the first (N+1) × 1 optical fiber pumping signal bundling device 21 injects fibre and is connected with 1 the second multimode optically pumped laser 22 respectively, the output fibre of the first (N+1) × 1 optical fiber pumping signal bundling device 21 is connected with one end of the second Double Cladding Ytterbium Doped Fiber 23, the input that the other end and the 3rd of the second Double Cladding Ytterbium Doped Fiber 23 remains pumping light decanter 24 is connected, the output of the 3rd residue pumping light decanter 24 connects the input of the 3rd fibre optic isolater 25.

Described same band draw power main amplifier 3 comprises the second (N+1) × 1 optical fiber pumping signal bundling device 31, with band PLM 32,3rd Double Cladding Ytterbium Doped Fiber 33,3rd (N+1) × 1 backward pump signal bundling device 34,4th residue pumping light decanter 35 and fiber-optic output cap 36, the output of the 3rd fibre optic isolater 25 connects the signal fibre of the second (N+1) × 1 optical fiber pumping signal bundling device 31, the N root pumping light injection fibre of the second (N+1) × 1 optical fiber pumping signal bundling device 31 is same with 1 group is respectively with PLM 32 to be connected, the output fibre of the second (N+1) × 1 optical fiber pumping signal bundling device 31 is connected with one end of the 3rd Double Cladding Ytterbium Doped Fiber 33, the other end of the 3rd Double Cladding Ytterbium Doped Fiber 33 is connected with the output fibre of the 3rd (N+1) × 1 backward pump signal bundling device 34, the N root pumping light injection fibre of the 3rd (N+1) × 1 backward pump signal bundling device 34 is same with 1 group is respectively with PLM 32 to be connected, the signal fibre of the 3rd (N+1) × 1 backward pump signal bundling device 34 is connected with the 4th input remaining pumping light decanter 35, the output of the 4th residue pumping light decanter 35 is connected with the input of fiber-optic output cap 36.

Superfluorescence seed light source 1 remains pumping light decanter 16, first fibre optic isolater 17, second fibre optic isolater 18 etc. by the first residue pumping light decanter 11, first side pump bundling device (combiner) 12, first multimode optically pumped laser 13, first Double Cladding Ytterbium Doped Fiber 14, second side pump bundling device 15, second and forms.First residue pumping light decanter 11 bears power and is not less than 50W, fiber core/inner cladding dimensions is respectively 20/400 μm, fibre core/the inner cladding dimensions that signal is fine and output is fine of the first side pump bundling device (combiner) 12 is respectively 20/400 μm, first multimode semiconductor laser 13 maximum power output 50W, centre wavelength 976nm, fibre core/the inner cladding dimensions of the first Double Cladding Ytterbium Doped Fiber 14 is respectively 20/400 μm, length 20m, second side pump bundling device 15 parameter is identical with the first side pump bundling device 12 parameter, it is identical that second residue pumping light decanter 16 and first remains pumping light decanter 11 parameter, first fibre optic isolater 17 bears power and is not less than 50W, fiber core/inner cladding dimensions is respectively 20/400 μm, anti-reflection within the scope of 1050 ~ 1150nm, introducing feedback to avoid isolator causes superfluorescence seed source self excitation threshold to reduce, second fibre optic isolater 18 parameter is identical with the first fibre optic isolater 17.The measure such as 8 ° of angles, another termination two wide spectrum optical fiber isolators is cut into because superfluorescence seed light source 1 takes one end, can effectively suppress end face and post-amplifier light echo on the impact of seed light source operating state, improve self excitation threshold, realize 20W superfluorescence seed and export.

Pre-power amplifier 2 is made up of the first (N+1) × 1 optical fiber pumping signal bundling device (combiner) 21, second multimode optically pumped laser 22, second Double Cladding Ytterbium Doped Fiber 23, the 3rd residue pumping light decanter the 24, the 3rd fibre optic isolater 25 etc.Fibre core/the inner cladding dimensions that signal is fine and output is fine of the first (N+1) × 1 optical fiber pumping signal bundling device 21 is respectively 20/400 μm, second multimode semiconductor laser 22 maximum power output 100W, centre wavelength 976nm, fibre core/the inner cladding dimensions of the second Double Cladding Ytterbium Doped Fiber 23 is respectively 20/400 μm, length 20m, 3rd residue pumping light decanter 24 bears power and is not less than 150W, fiber core/inner cladding dimensions is respectively 20/400 μm, 3rd fibre optic isolater 25 bears power and is not less than 150W, fiber core/inner cladding dimensions is respectively 20/400 μm, anti-reflection within the scope of 1050 ~ 1150nm.

With band draw power main amplifier 3 by the second (N+1) × 1 optical fiber pumping signal bundling device 31, with being with PLM 32, the 3rd Double Cladding Ytterbium Doped Fiber 33, the 3rd (N+1) × 1 backward pump signal bundling device the 34, the 4th residue pumping light decanter 35 and fiber-optic output cap 36 etc. to form.Fibre core/the inner cladding dimensions of the signal fibre of the second (N+1) × 1 optical fiber pumping signal bundling device 31 is respectively 20/400 μm, pumping light injects long and slender core/cladding size and is respectively 200/220 μm, export long and slender core/inner cladding dimensions and be respectively 50/400 μm, 6 pumping light injection fibres of the second (N+1) × 1 optical fiber pumping signal bundling device 31 are same with 6 is respectively with PLM 32 to be connected, with being with pumping laser wavelength to be 1018nm, each module is by 7 output optical fibres 15/130 μm, the oscillator of power 160W and 7 × 1 pumping combiner devices are formed, module output optical fibre fibre core/cladding size is respectively 200/220 μm, fibre core/the inner cladding dimensions of the 3rd Double Cladding Ytterbium Doped Fiber 33 is respectively 50/400 μm, length is 30m, the output of the 3rd (N+1) × 1 backward pump signal bundling device 34 is fine identical with the fine model of signal, fibre core/inner cladding dimensions is respectively 50/400 μm, pumping light injects fine fibre core/cladding size and is respectively 200/220 μm, 6 same band pumping laser exported with band PLM 32 inject the 3rd Double Cladding Ytterbium Doped Fiber 33 through 6 pumping light injection fibres of the 3rd (N+1) × 1 backward pump signal bundling device 34, fibre core/the inner cladding dimensions of the tail optical fiber of residue pumping light decanter 35 and fiber-optic output cap 36 is respectively 50/400 μm, bear power and be greater than 10kW.

Superfluorescence seed light source 1 power output is 20W, is amplified to after 150W power level and injects with band draw power main amplifier 3, at 13.4kW with under the pumping of being with pumping laser, realize myriawatt level superfluorescence and export through Pre-power amplifier 2.Because super-fluorescence light source has compared with laser, non-mode is competed, without relaxation oscillation, without outstanding features such as weak locked mode, high time-domain stability, this all-fiber MOPA structure superfluorescent fiber sources is with a wide range of applications in fields such as industrial processes.

The above is only preferred implementation of the present utility model, and protection range of the present utility model is also not only confined to above-described embodiment.All technical schemes belonged under the utility model thinking all belong to protection range of the present utility model.It is noted that for those skilled in the art, the improvements and modifications under the prerequisite not departing from the utility model principle, these improvements and modifications also should be considered as protection range of the present utility model.

Claims (8)

1. based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: comprise superfluorescence seed light source, Pre-power amplifier and same band draw power main amplifier;

Described superfluorescence seed light source is a kind of Yb dosed optical fiber amplified spontaneous emission source, it comprises the first residue pumping light decanter, first side pump bundling device, first multimode optically pumped laser, first Double Cladding Ytterbium Doped Fiber, second side pump bundling device, second residue pumping light decanter, first fibre optic isolater, second fibre optic isolater, output end-grain cutting 8 ° of oblique angles of first residue pumping light decanter are to export monitoring ASE, input is connected with the signal fibre of the first side pump bundling device, every root pumping light of the first side pump bundling device injects fibre and is connected with 1 the first multimode optically pumped laser respectively, the output fibre of the first side pump bundling device is connected with one end of the first Double Cladding Ytterbium Doped Fiber, the other end of the first Double Cladding Ytterbium Doped Fiber is connected with the output of the second side pump bundling device, every root pumping light of the second side pump bundling device injects fibre and is connected with 1 the first multimode optically pumped laser respectively, the signal fibre of the second side pump bundling device connects one end of the second residue pumping light decanter, the other end of the second residue pumping light decanter is connected with the input of the first fibre optic isolater, the output of the first fibre optic isolater is connected with the input of the second fibre optic isolater,

Described Pre-power amplifier comprises the first (N+1) × 1 optical fiber pumping signal bundling device, second multimode optically pumped laser, second Double Cladding Ytterbium Doped Fiber, 3rd residue pumping light decanter, 3rd fibre optic isolater, the signal fibre of output and first (N+1) × 1 optical fiber pumping signal bundling device of the second fibre optic isolater is connected, the N root pumping light of the first (N+1) × 1 optical fiber pumping signal bundling device injects fibre and is connected with 1 the second multimode optically pumped laser respectively, the output fibre of the first (N+1) × 1 optical fiber pumping signal bundling device is connected with one end of the second Double Cladding Ytterbium Doped Fiber, the input that the other end and the 3rd of the second Double Cladding Ytterbium Doped Fiber remains pumping light decanter is connected, the output of the 3rd residue pumping light decanter connects the input of the 3rd fibre optic isolater,

Described same band draw power main amplifier comprises the second (N+1) × 1 optical fiber pumping signal bundling device, with being with PLM, 3rd Double Cladding Ytterbium Doped Fiber, 3rd (N+1) × 1 backward pump signal bundling device, 4th residue pumping light decanter and fiber-optic output cap, the output of the 3rd fibre optic isolater connects the signal fibre of the second (N+1) × 1 optical fiber pumping signal bundling device, the N root pumping light injection fibre of the second (N+1) × 1 optical fiber pumping signal bundling device is same with 1 group is respectively with PLM to be connected, the output fibre of the second (N+1) × 1 optical fiber pumping signal bundling device is connected with one end of the 3rd Double Cladding Ytterbium Doped Fiber, the other end of the 3rd Double Cladding Ytterbium Doped Fiber is connected with the output fibre of the 3rd (N+1) × 1 backward pump signal bundling device, the N root pumping light injection fibre of the 3rd (N+1) × 1 backward pump signal bundling device is same with 1 group is respectively with PLM to be connected, the signal fibre of the 3rd (N+1) × 1 backward pump signal bundling device is connected with the 4th input remaining pumping light decanter, the output of the 4th residue pumping light decanter is connected with the input of optical fiber end cap.

2. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: the first described multimode optically pumped laser and the centre wavelength of the second multimode optically pumped laser are λ 1,800nm≤λ 1≤1000nm.

3. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: the first described Double Cladding Ytterbium Doped Fiber is monomode fiber or multimode large core fiber, the second Double Cladding Ytterbium Doped Fiber and the 3rd Double Cladding Ytterbium Doped Fiber are multimode large core fiber.

4. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: the first described residue pumping light decanter and the second residue pumping light decanter are monomode fiber or the multimode large core fiber of mixing germanium, and its numerical aperture and physical dimension are mated with the first side pump bundling device, the second side pump bundling device respectively; 3rd residue pumping light decanter and the 4th residue pumping light decanter are the multimode large core fiber mixing germanium, and its numerical aperture and physical dimension are mated with the second Double Cladding Ytterbium Doped Fiber, the 3rd Double Cladding Ytterbium Doped Fiber respectively.

5. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: the model that the first described fibre optic isolater, the tail optical fiber type of the second fibre optic isolater and second remain pumping light decanter tail optical fiber is identical, bear power and be not less than 50W, anti-reflection within the scope of 1050 ~ 1150nm, introduce feedback to avoid isolator and cause superfluorescence seed source self excitation threshold to reduce; The model that the fiber type and the 3rd of the 3rd fibre optic isolater remains pumping light decanter tail optical fiber is identical, bears power and is not less than 150W, anti-reflection within the scope of 1050 ~ 1150nm.

6. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: the model of the first described (N+1) × 1 optical fiber pumping signal bundling device, the signal fibre of the second (N+1) × 1 optical fiber pumping signal bundling device is identical with the tail optical fiber model of the second fibre optic isolater, the 3rd fibre optic isolater respectively, the signal of the 3rd (N+1) × 1 backward pump signal bundling device is fine, export fine physical dimension with the 3rd Double Cladding Ytterbium Doped Fiber, numerical aperture is identical; All the pumping light injection end of (N+1) × 1 optical fiber pumping signal bundling device is N number of, 1≤N≤200.

7. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: described same band PLM, its centre wavelength is λ ₂, 1000nm≤λ ₂≤ 1040nm; Each with being with PLM to form by 7 number hectowatt grade oscillators and 7 × 1 pumping combiner devices.

8. according to claim 1 based on the high power all-fiber MOPA structure superfluorescent fiber sources with band pumping, it is characterized in that: the tail optical fiber model that the tail optical fiber model and the 4th of described fiber-optic output cap remains pumping light decanter is identical, anti-reflection within the scope of 1050 ~ 1150nm.