Low-noise Raman amplifier

What is claimed is: 1. A low-noise amplifier, comprising: a gain medium; a first amplifier stage configured to receive an input optical signal and to output a first combined optical signal, the first amplifier stage comprising: a first optical filter configured to pass all wavelengths of the input optical signal through the first optical filter in a first propagation direction over the gain medium and to reflect first wavelengths above a first threshold wavelength received by the first optical filter over the gain medium in a direction opposite the first propagation direction; and a first Raman pump configured to inject a first pump light onto the gain medium for transmission in the first propagation direction, the first pump light being centered at a wavelength lower than the first threshold wavelength, the first Raman pump comprising a first Fabry Perot laser configured to generate the first pump light, and comprising a first temperature controller configured to tune the first Fabry Perot laser to shift the wavelength at which the first pump light is centered toward the wavelength lower than the first threshold wavelength; and a second amplifier stage configured to receive the first combined optical signal and to output a second combined optical signal, the second amplifier stage comprising: a second optical filter configured to pass all wavelengths of the first combined optical signal through the second optical filter in the first propagation direction over the gain medium and to reflect second wavelengths above a second threshold wavelength received by the second optical filter over the gain medium in a direction opposite the first propagation direction; and a second Raman pump configured to inject a second pump light onto the gain medium for transmission in the first propagation direction, the second pump light being centered at a wavelength lower than the second threshold wavelength, the second Raman pump comprising a second Fabry Perot laser configured to generate the second pump light, and comprising a second temperature controller configured to tune the second Fabry Perot laser to shift the wavelength at which the second pump light is centered toward the wavelength lower than the second threshold wavelength; wherein the first combined optical signal includes all wavelengths of the input optical signal and the first pump light, and the second combined optical signal includes all wavelengths of the first combined optical signal and the second pump light. 2. The amplifier of claim 1 , further comprising at least one additional amplifier stage, each additional amplifier stage being configured to receive a combined optical signal from a previous amplifier stage and to output a respective combined optical signal, and each additional amplifier stage comprising: a respective optical filter configured to pass all wavelengths of the received combined optical signal through the respective optical filter in the first propagation direction over the gain medium and to reflect respective wavelengths above a respective threshold wavelength received by the respective optical filter over the gain medium in a direction opposite the first propagation direction, the respective threshold wavelength being lower than a threshold wavelength at the previous amplifier stage; and a respective Raman pump configured to inject a respective pump light onto the gain medium for transmission in the first propagation direction, the respective pump light being centered at a wavelength lower than the respective threshold wavelength; wherein the respective combined optical signal output by the additional amplifier stage includes all wavelengths of the received combined signal and the respective pump light. 3. The amplifier of claim 2 , wherein: the first threshold wavelength is approximately 1520 nanometers; the first pump light is centered at a wavelength of approximately 1510 nanometers; the second threshold wavelength is approximately 1490 nanometers; the second pump light is centered at a wavelength of approximately 1480 nanometers; the respective threshold wavelength of a third amplifier stage is approximately 1460 nanometers; the respective pump light injected into the gain medium at the third amplifier stage is centered at a wavelength of approximately 1450 nanometers; the respective threshold wavelength of a fourth amplifier stage is approximately 1430 nanometers; and the respective pump light injected into the gain medium at the fourth amplifier stage is centered at a wavelength of approximately 1420 nanometers. 4. The amplifier of claim 1 , wherein: the first Raman pump is configured to shift the wavelength at which the first pump light is centered toward the wavelength lower than the first threshold wavelength responsive to a first tuning current; and the second Raman pump is configured to shift the wavelength at which the second pump light is centered toward the wavelength lower than the second threshold wavelength responsive to a second tuning current. 5. The amplifier of claim 1 , further comprising an isolator configured to isolate the amplifier from signals propagated toward the amplifier in a direction counter to the first propagation direction. 6. The amplifier of claim 1 , wherein: the amplifier is a discrete Raman amplifier; and the gain medium is a fiber exhibiting a chromatic dispersion of more than 4 picoseconds per nanometer of wavelength change per kilometer of propagation distance. 7. The amplifier of claim 1 , wherein: the amplifier is a distributed Raman amplifier; and the gain medium is an optical transmission fiber. 8. The amplifier of claim 1 , wherein the input optical signal is a wavelength division multiplexed (WDM) signal. 9. A method for low-noise amplification of optical signals, comprising: receiving, at a first stage of an amplifier, an input optical signal; passing all wavelengths of the input optical signal through a first optical filter in a first propagation direction over a gain medium, the first optical filter reflecting first wavelengths above a first threshold wavelength received by the first optical filter over the gain medium in a direction opposite the first propagation direction; generating a first pump light at a first Rama pump using a first Fabry Perot laser; tuning, using a first temperature controller, the first Fabry Perot laser to shift a wavelength at which the first pump light is centered toward a wavelength lower than the first threshold wavelength; injecting the first pump light from the first Raman pump onto the gain medium for transmission in the first propagation direction; providing, over the gain medium, a first combined optical signal including all wavelengths of the input optical signal and the first pump light to a second stage of the amplifier; receiving, at the second stage of the amplifier, the first combined optical signal; passing all wavelengths of the first combined optical signal, including the first pump light, through the second optical filter in the first propagation direction over the gain medium, the second optical filter reflecting second wavelengths above a second threshold wavelength received by the second optical filter over the gain medium in a direction opposite the first propagation direction, the second threshold wavelength being lower than the first threshold wavelength; generating a second pump light at the second Raman pump using a second Fabry Perot laser; tuning, using a second temperature controller, the second Fabry Perot laser to shift a wavelength at which the second pump light is centered toward a wavelength lower than the second threshold wavelength; injecting the second pump light from the second Raman pump onto the gain