Monolithic integrated seed and high power pump source

What is claimed: 1. An integrated seed and high power pump source, comprising: a pump power oscillator comprising a first medium having a pump wavelength (λp), a leaky high reflector fiber Bragg grating (FBG), and a partially reflective (PR) FBG, where the pump power oscillator intentionally propagates a minor portion of pump wavelength (λp) radiation in the reverse direction through the leaky high reflector fiber Bragg grating (FBG) and propagates a major portion of pump wavelength (λp) radiation in the forward direction through the partially reflective FBG; the first medium having a gain bandwidth and an emission bandwidth, wherein the gain bandwidth is the width of the optical frequency range in which significant gain is available from an amplifier; a seed pre-amplifier comprising a second medium having a seed wavelength (λs) wherein the seed pre-amplifier is pumped by the reverse propagating pump wavelength (λp) radiation leaked backwards through a reflection of the leaky high reflector fiber Bragg grating (FBG); and a seed power amplifier comprising the second medium having the seed wavelength (λs) wherein the seed power amplifier is pumped by the forward propagating pump wavelength (λp) radiation through the transmission of the partially reflective FBG, wherein the seed wavelength (λs) is outside the gain bandwidth of the first medium, but within the emission bandwidth of the first medium, and the seed wavelength (λs) when pumped by the pump wavelength (λp) experiences gain in the second medium; and the pump wavelength (λp) lies in a spectrally overlapped region of the first medium and the second medium, such that there is gain in the first medium and absorption in the second medium; thereby combining and amplifying a dual wavelength source in a monolithic fiber amplifier. 2. The integrated seed and high power pump source of claim 1 , wherein the first medium is thulium-doped silica fiber. 3. The integrated seed and high power pump source of claim 2 , wherein the seed wavelength (λs) is about 2110 nm. 4. The integrated seed and high power pump source of claim 1 , wherein the second medium is holmium-doped silica fiber. 5. The integrated seed and high power pump source of claim 4 , wherein the pump wavelength (λp) is about 1920 nm. 6. The integrated seed and high power pump source of claim 1 , wherein the seed pre-amplifier further comprises a seed diode. 7. The integrated seed and high power pump source of claim 1 , wherein the pump power oscillator further comprises a pump/signal combiner. 8. The integrated seed and high power pump source of claim 7 , wherein the pump/signal combiner is pumped by a pump source having a pump source wavelength (λp 2 ). 9. The integrated seed and high power pump source of claim 8 , wherein the pump source wavelength (λp 2 ) is about 795 nm. 10. A method of pumping integrated amplifiers with a single pump source comprising: providing a pump power oscillator comprising a first medium having a pump wavelength (λp), a leaky high reflector fiber Bragg grating (FBG), and a partially reflective FBG; providing a seed pre-amplifier comprising a second medium having a seed wavelength (λs); providing a seed power amplifier comprising the second medium having the seed wavelength (λs); propagating pump wavelength (λp) radiation from the pump power oscillator, In a forward direction, through the partially reflective FBG; pumping the seed power amplifier with the forward propagating pump wavelength (λp) radiation via the transmission of the partially reflective FBG; propagating pump wavelength (λp) radiation from the pump power oscillator, in a reverse direction, through the leaky high reflector FBG; and pumping the seed pre-amplifier with the reverse propagating pump wavelength (λp) radiation leaked backward via the reflection of the leaky high reflector FBG, wherein the seed wavelength (λs) is outside a practical gain bandwidth of the first medium, but within an emission bandwidth of the first medium, wherein being outside the practical gain bandwidth is where the gain is extremely low, so it is not to practical to use for applications requiring high-efficiency amplification, and the seed wavelength {λs), when pumped by the pump wavelength (λp), experiences gain in the second medium, and the pump wavelength (λp) lies in a spectrally overlapped region of the first medium and the second medium, such that there is gain in the first medium and absorption in the second medium, thereby combining and amplifying a dual wavelength source in a monolithic fiber amplifier. 11. The method of pumping integrated amplifiers with a single pump source of claim 10 , wherein the first medium is thulium-doped silica fiber. 12. The method of pumping integrated amplifiers with a single pump source of claim 10 , wherein the second medium is holmium-doped silica fiber. 13. The method of pumping integrated amplifiers with a single pump source of claim 10 , wherein the seed wavelength (λs) is about 2110 nm and the pump wavelength (λp) is about 1920 nm. 14. The method of pumping integrated amplifiers with a single pump source of claim 10 , wherein the seed pre-amplifier further comprises a seed diode. 15. The method of pumping integrated amplifiers with a single pump source of claim 10 , wherein the pump power oscillator further comprises a pump signal combiner and is pumped by a pump source having a pump source wavelength (λp 2 ). 16. The method of pumping integrated amplifiers with a single pump source of claim 10 , wherein the pump source wavelength (λp 2 ) is about 795 nm.