Optical amplifier module

What is claimed is: 1. An optical amplifier for providing fiber-based amplification of an optical signal propagating along an incoming optical transmission signal path, the optical amplifier comprising a fiber amplifier arrangement; and a multi-stage optical amplifier module coupled to the fiber amplifier arrangement, the multi-stage optical amplifier module including an input stage responsive to an incoming optical signal and an amplifying light input; and an output stage for providing an amplified signal as the optical amplifier output, wherein the multi-stage optical amplifier is disposed within a housing including optical inputs, optical outputs, electrical inputs and electrical outputs, with each stage supporting the transmission of the incoming optical signal, amplifying light, and amplified optical signal as free-space beams and including a plurality of discrete optical components to interact with the free-space beams and provide the amplified optical output signal, the plurality of discrete optical components including a plurality of turning mirrors for providing the optical inputs and optical outputs along a common sidewall of the housing. 2. The optical amplifier of claim 1 wherein the input stage of the multi-stage amplifier module is responsive to the input optical signal and the amplifying light input, the optical signal and the amplifying light input propagating as free-space beams within the input stage and manipulated by a plurality of discrete optical components disposed within the input stage to be combined to co-propagate along a common signal path exiting the housing along the common sidewall and thereafter applied as an input to the fiber amplifier arrangement. 3. The optical amplifier of claim 1 wherein the optical amplifier further comprises a post-amplifier stage disposed between the input stage and the output stage of the multi-stage amplifier module, the post-amplifier stage responsive to the free-space beam amplified optical signal created by fiber amplifier arrangement, the post-amplifier stage including a discrete optical filter component disposed to perform filtering on the free-space beam amplified optical signal; and the output stage of the multi-stage amplifier module is responsive to a filtered, amplified optical output signal from the post-amplifier stage and supports the propagation of a free-space beam representation of the filtered, amplified optical output signal, the output stage including a plurality of discrete optical components include an optical tap and a monitoring photodiode, the propagating filtered, amplified free-space beam directed through the optical tap to direct a relatively small portion of the free-space beam into the monitoring photodiode and direct the remainder of free-space beam along the output signal path exiting the housing along the common sidewall. 4. The optical amplifier module as defined in claim 2 wherein the discrete optical components of the input stage of the multi-stage optical amplifier module comprise a first optical lens disposed at an entrance port along the common sidewall of the housing, the first optical lens responsive to the incoming optical signal and creating a collimated free-space beam version thereof; a first turning mirror for intercepting the collimated free-space beam from the first optical lens and re-directing the collimated free-space beam in a different direction; an optical isolator disposed to intercept the re-directed free-space beam; a second turning mirror for intercepting the re-directed free-space beam and re-orienting the collimated free-space beam in a direction toward the optical output along the housing common sidewall; and a second optical lens disposed between an exit port of the input stage along the common sidewall and the second turning mirror for focusing the collimated free-space beam into output signal path, wherein the angular positioning of the first and second turning mirrors are adjustable to minimize insertion loss between the input and the output of the input stage. 5. The optical amplifier as defined in claim 4 wherein the discrete optical components of the input stage of the multi-stage optical amplifier module further comprise: a dual-path fiber pigtail coupled to the common sidewall and including a first path for supporting the propagation of incoming pump light and a second path for supporting the propagation of out-going co-propagating input optical signal and amplifying light, directing the co-propagating input optical signal and amplifying light into the fiber amplifier arrangement; and a discrete wavelength division multiplexer element disposed between the second turning mirror and the second optical lens, the discrete wavelength division multiplexer element receiving the incoming free-space amplifying light and reflecting the free-space amplifying light into the second optical lens, the amplifying light thereafter coupled into the second path with the incoming optical signal. 6. The optical amplifier as defined in claim 4 wherein the input stage of the multi-stage optical amplifier module further comprises a discrete laser diode pump source, the discrete laser diode including electrical contacts coupled to an electrical input and an electrical output of the housing and positioned within the input stage to direct a free-space amplifying light beam through the second turning mirror and into the second optical lens, combining with the free-space input optical signal beam to create the co-propagating beams as the optical output of the input stage exiting along the common sidewall. 7. The optical amplifier as defined in claim 1 wherein the optical amplifier is based upon amplification in a fiber including a rare earth dopant and uses a pump source as the amplifying light, providing pump light at a predetermined wavelength associated with creating optical gain in the presence of the rare earth dopant. 8. The optical amplifier as defined in claim 1 wherein the optical amplifier comprises a distributed Raman amplifier, and the includes an amplifying light source in the form of a high power pulse source for injecting high-energy optical pulses into the fiber amplifier in combination with the incoming optical signal. 9. The optical amplifier as defined in claim 8 wherein the optical amplifier comprises a distributed Raman amplifier, disposed to inject high-energy optical pulses into a section of optical fiber within the fiber amplifier arrangement. 10. The optical amplifier as defined in claim 3 wherein the discrete optical components disposed within the post-amplifier stage of the multi-stage optical amplifier module include a first optical lens disposed at an optical input along the common housing sidewall, the first optical lens responsive to an incoming amplified optical signal from the fiber amplifier arrangement and creating a free-space beam version thereof; a first turning mirror disposed to intercept the collimated, amplified free-space beam from the first optical lens and re-direct the collimated, amplified free-space beam in a different direction; an optical isolator disposed to intercept the re-directed free-space beam; and a gain filter disposed at the output of the optical isolator, the gain filter comprising a thin film discrete filter element for modifying a gain profile of the collimated, amplified free-space beam. 11. The optical amplifier as defined in claim 10 wherein the gain filter comprises a gain flattening filter, creating a uniform gain profile across the wavelength spectrum of the collimated, amplified beam. 12. The optical amplifier as defined in claim 10 , wherein discrete optical components of the post-ampli