High power fiber pump source with high brightness, low-noise output in about 974-1030 nm wavelength

The invention claimed is: 1. A high power ultra-bright pump and low noise source (“HPUBLNS”), comprising: at least one seed source generating a low-noise signal light a wavelength λp; a plurality of high power (“HP”) semiconductor laser diodes combined together to radiate sub-pump emission at a sub-pump wavelength λsp; and an Yb-doped multimode (“MM”) fiber wavelength converter of the sub-pump emission at the sub-pump wavelength λsp to a pump output at the wavelength λp which is configured to emit a pump output at the wavelength λp and having: a noise level substantially identical to those of the low-noise signal light, a brightness (“B”) substantially equal to n×B, wherein n is a number HP semiconductor laser diodes, and B is brightness of each HP laser diode, and an output power (“Po”) substantially equal to nPd, wherein Pd is a power of each HP laser diode, and n is the number thereof. 2. The HPUBLNS of claim 1 further comprising a delivery fiber with a core receiving and guiding the amplified low noise pump output, the core of the delivery fiber being configured with a core diameter smaller than that one of a MM combiner pump source, provided the MM combiner pump source emits an output light with a power substantially equal to the pump output, wherein the brightness of the pump output is at least in 10 (ten) or more times greater than brightness of the output light of the MM combiner. 3. The HPUBLNS of claim 1 , wherein the wavelength converter is configured so that the amplified low noise pump output has a root-mean-square (r.m.s.) value at most 0.1% m.r.s. 4. The HPUBLNS of claim 2 , wherein the seed source has a configuration selected from a group consisting of one or more combined MM pigtailed laser diodes and one or more SM fiber oscillators. 5. The HPUBLNS of claim 1 , wherein the sub-pump wavelength λ sp varies between about 910-975 nm wavelength range. 6. The HPUBLNS of claim 4 , wherein the wavelength converter is configured with a MM YB doped fiber and input and output passive MM fibers which are spliced to respective opposite ends of the Yb-doped fiber and have a uniform core diameter which is substantially equal to the core diameter of the delivery fiber spliced to the output passive fiber. 7. The HPUBLNS of claim 1 , wherein the semiconductor laser diodes are configured to end-pump the wave-length fiber converter or side pump the wavelength fiber converter. 8. The HPUBLNS of claim 1 , wherein a numerical aperture of the Yb wavelength converter ranges between about 0.05 and about 0.13, whereas a numerical aperture of the MM seed source varies between about 0.1 and about 0.13. 9. The HPUBLNS of claim 1 further comprising a SM Yb-doped optical fiber oscillator receiving the amplified low-noise pump light and operative to generate a SM light output at a wavelength greater than the pump output wavelength λp. 10. The HPUBLNS of claim 9 , wherein the SM Yb optical oscillator includes: a double clad Yb-doped fiber with a MM core which is configured to support substantially a single, fundamental mode in a desired wavelength range, spaced double-clad input and output passive fibers spliced to respective opposite ends of the Yb-doped fiber and having respective single-mode cores, and a pair of fiber Bragg gratings each provided in the SM core of the passive fiber so that the Yb laser outputs the SM pump light in the fundamental mode in an about 1015-1030 nm wavelength range. 11. The HPUBLNS of claim 6 , wherein the core of the Yb-doped fiber of the MM wavelength converter has a core diameter of up to about 300 μm. 12. The HPUBLNS of claim 1 further comprising at least one additional HPPS, wherein the plurality of HPUBLNSs are optically combined to end pump an Yb gain block. 13. The HPUBLNS of claim 1 further comprising at least one additional HPPS, wherein multiple HPPLNSs are optically combined to side pump an Yb gain block. 14. The HPUBLNS of claim 1 , wherein the wavelength converter has an Yb-doped MM fiber configured with an Yb-ion concentration ranging between about 10 and 200 ppm. 15. The HPUBLNS of claim 2 wherein the core of the delivery fiber is at least of 50 micron. 16. The HPUBLNS of claim 1 , wherein Δλ=λ p −λ sp <0.1λ sp , where λ p —is the wavelength of pump output and λ sp is the sub-pump wavelength. 17. A high power ultra-bright lows noise pump source (“HPUBLNS”), comprising; at least one seed source generating a spike-less low-noise signal light; and an Yb-doped multimode (“MM”) fiber wavelength converter of emission of a plurality of pump laser diodes at a sub-pump wavelength λ sp to a pump output at a wavelength λ p , wherein λ sp # λ p , the MM wavelength converter being configured to amplify the signal light so that the pump output has brightness substantially exceeding brightness of and a noise level at most equal to that one of the low-noise signal light. 18. The HPUBLNS of claim 17 further comprising a SM Yb-doped optical fiber oscillator receiving the amplified pump output and operative to generate a SM light source output at a wavelength greater than the pump output wavelength λp. 19. The HPUBLNS of claim 18 , wherein the SM Yb optical oscillator includes: a double clad Yb-doped fiber with a MM core which is configured to support substantially a single, fundamental mode in a desired wavelength range, spaced double-clad input and output passive fibers spliced to respective opposite ends of the Yb-doped fiber and having respective single-mode cores, and a pair of fiber Bragg gratings each provided in the SM core of the passive fiber so that the Yb laser outputs the SM pump light in the fundamental mode in an about 1015-1030 nm wavelength range. 20. The HPUBLNS of claim 18 , wherein the seed has a configuration selected from pigtailed laser diodes or one or mode SM fiber oscillators.