Optical scanning assembly and method of inspecting a channel

What is claimed is: 1. An optical scanning assembly for use in inspecting a channel, said assembly comprising: a housing comprising a hollow insertion portion configured to maintain said housing in a reference position when inspecting the channel; an inspection probe configured to selectively advance through said hollow insertion portion and into the channel along an axis, wherein said inspection probe comprises a light source configured to direct light towards at least one side wall of the channel and a light detector configured to receive the light reflected from the at least one side wall; and a controller in communication with said inspection probe, said controller configured to: obtain a first optical length measurement for the light reflected from the at least one side wall when the inspection probe is in a first position along the axis within the channel; obtain a second optical length measurement for the light reflected from the at least one side wall when the inspection probe is in a second position along the axis within the channel; and compare the first and second optical length measurements to determine variations in a geometry of the channel. 2. The assembly in accordance with claim 1 , wherein said inspection probe is configured to rotate about the axis, said controller further configured to: obtain a plurality of optical length measurements as the inspection probe rotates about the axis such that a first set of optical length measurements is obtained when the inspection probe is at the first position along the axis, and such that a second set of optical length measurements is obtained when the inspection probe is at the second position along the axis. 3. The assembly in accordance with claim 1 , wherein said inspection probe comprises a beam splitter positioned such that a first portion of the light is directed towards the at least one side wall of the channel, and such that a second portion of the light is directed towards an end wall of the channel. 4. The assembly in accordance with claim 3 further comprising a range detector coupled to said inspection probe, wherein said range detector is positioned to receive the second portion of the light reflected from the end wall. 5. The assembly in accordance with claim 1 , wherein said inspection probe comprises a stationary portion and a rotatable tip portion configured to rotate relative to said stationary portion, said light source configured to direct the light from said rotatable tip portion. 6. The assembly in accordance with claim 1 , wherein said light source comprises a light outlet configured to channel the light therethrough and towards the at least one side wall of the channel, said light outlet substantially aligned with said light detector relative to the axis. 7. The assembly in accordance with claim 1 , wherein said light source comprises a fiber optic cable configured to channel the light therethrough. 8. The assembly in accordance with claim 1 , wherein said light source and said light detector comprise at least one micro-opto-electro-mechanical system. 9. An optical scanning assembly for use in inspecting a structure including a channel, said assembly comprising: a housing configured to couple to the structure, said housing comprising a hollow insertion portion configured to maintain said housing in a reference position when inspecting the channel; and an inspection probe configured to selectively advance through said hollow insertion portion and into the channel along an axis, wherein said inspection probe comprises a light source configured to direct light towards at least one side wall of the channel and a light detector configured to receive the light reflected from the at least one side wall, such that at least one optical length measurement of the light reflected from the at least one side wall is obtained as said inspection probe advances along the axis. 10. The assembly in accordance with claim 9 further comprising at least one stabilizing foot coupled to said housing, said at least one stabilizing foot configured to couple to the structure to substantially maintain said inspection probe in a reference position. 11. The assembly in accordance with claim 9 , wherein said hollow insertion portion is sized to extend at least partially through an opening in the channel. 12. The assembly in accordance with claim 9 , wherein said inspection probe comprises a stationary portion and a rotatable tip portion configured to rotate relative to said stationary portion, said light source configured to direct the light from said rotatable tip portion. 13. The assembly in accordance with claim 9 , wherein said light source comprises a light outlet configured to channel the light therethrough and towards the at least one side wall of the channel, said light outlet substantially aligned with said light detector relative to the axis. 14. The assembly in accordance with claim 9 , wherein said light source comprises a fiber optic cable configured to channel the light therethrough. 15. The assembly in accordance with claim 9 , wherein said light source and said light detector comprise at least one micro-opto-electro-mechanical system. 16. A method of inspecting a channel with an optical scanning assembly including a housing and an inspection probe, the channel accessible through a perforation in the face sheet, the inspection probe including a light source configured to direct light towards at least one side wall of the channel and a light detector configured to receive the light reflected from the at least one side wall, said method comprising: positioning a hollow insertion portion of the housing within the perforation in the face sheet such that the housing is maintained in a reference position relative to the face sheet; advancing the inspection probe through the hollow insertion portion and into the channel along an axis that extends through the channel; obtaining a first optical length measurement for the light reflected from the at least one side wall when the inspection probe is in a first position along the axis within the channel; obtaining a second optical length measurement for the light reflected from the at least one side wall when the inspection probe is in a second position along the axis within the channel; and comparing the first and second optical length measurements to determine variations in a geometry of the channel. 17. The method in accordance with claim 16 further comprising selecting the first optical length measurement as a reference measurement for comparison to further optical length measurements. 18. The method in accordance with claim 16 further comprising rotating the inspection probe about the axis such that a first set of optical length measurements is obtained when the inspection probe is at the first position along the axis, and such that a second set of optical length measurements is obtained when the inspection probe is at the second position along the axis. 19. The method in accordance with claim 18 further comprising obtaining the second set of optical length measurements continuously as the inspection probe advances along the axis and rotates about the axis. 20. The method in accordance with claim 18 further comprising obtaining a plurality of sets of optical length measurements as the inspection probe is positioned at predetermined intervals along the axis.