Optical defect detection system

What is claimed is: 1 . An in-situ system for a gas turbine engine blade inspection comprising: a sensor system configured to capture images of a forward surface of at least one gas turbine engine blade; a processor coupled to the sensor system, the processor configured to determine damage to the at least one gas turbine engine blade based on image analytics; an illumination source in operative communication with the forward surface of at least one gas turbine engine blade; and a tangible, non-transitory memory configured to communicate with the processor, the tangible, non-transitory memory having instructions stored therein that, in response to execution by the processor, cause the processor to perform operations comprising: receiving, by the processor, data for the forward surface of at least one gas turbine engine blade from the sensor system; and determining, by the processor, surface damage responsive to the light source. 2 . The in-situ system for gas turbine engine blade inspection of claim 1 , wherein the illumination source is selected from the group consisting of a polarized light, an infrared light and a laser mesh pattern of light. 3 . The in-situ system for gas turbine engine blade inspection of claim 1 , further comprising: a polarization filter in operative communication with the sensor system. 4 . The in-situ system for gas turbine engine blade inspection of claim 1 , wherein the sensor system comprises at least one of a CMOS sensor and a polarization camera. 5 . The in-situ system for gas turbine engine blade inspection of claim 1 , wherein an IR cut-off filter is disabled from the CMOS sensor. 6 . The in-situ system for gas turbine engine blade inspection of claim 1 , wherein the illumination source is configured to emit linearly polarized light, the linearly polarized light being turned into an elliptically polarized light responsive to reflection off of the surface damage. 7 . The in-situ system for gas turbine engine blade inspection of claim 1 , further comprising: at least one of a combination of optical lens and light interference devices operatively coupled to the illumination source, and laser lines produced by an array of cylindrical lenses or a combination of one or more Powell lenses operatively coupled to the illumination source. 8 . The in-situ system for gas turbine engine blade inspection of claim 7 , wherein the illumination source is configured to produce a mesh or a series of lines projected onto the forward surface of the at least one gas turbine engine blade. 9 . The in-situ system for gas turbine engine blade inspection of claim 8 , wherein the illumination source creates a kink or discontinuity on a smooth curve of the mesh or lines responsive to illumination of the surface damage. 10 . The in-situ system for gas turbine engine blade inspection of claim 1 , wherein said gas turbine engine blade is selected from the group consisting of a fan blade a vane, a compressor blade, a compressor vane, a turbine blade, and a turbine vane. 11 . A method for in-situ inspection of a gas turbine engine fan, comprising: positioning a sensor to capture images of a surface of at least one gas turbine engine fan blade; positioning an illumination source in operative communication with the surface of at least one gas turbine engine blade; coupling a processor to the sensor, the processor configured to determine damage to the at least one gas turbine engine fan blade based on image analytics; wherein the processor performs operations comprising: receiving, by the processor, imaging data for the forward surface of at least one gas turbine engine fan blade from the sensor system; and determining, by the processor, surface damage responsive to the light source. 12 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , wherein the illumination source is selected from the group consisting of a polarized light, an infrared light and a laser mesh pattern of light. 13 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , further comprising: operatively coupling a polarization filter with the sensor system. 14 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , further comprising: disabling an IR cut-off filter from a CMOS sensor. 15 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , further comprising: configuring the light source to emit linearly polarized light; and turning the linearly polarized light into an elliptically polarized light responsive to reflection off of the surface damage. 16 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , further comprising: operatively coupling the illumination source to at least one of a combination of optical lens and light interference devices, and laser lines produced by an array of cylindrical lenses or a combination of one or more Powell lenses. 17 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , further comprising: configuring the illumination source to produce a mesh or a series of lines projected onto the forward surface of the at least one gas turbine engine blade. 18 . The method for in-situ inspection of a gas turbine engine fan of claim 17 , further comprising: creating a kink or discontinuity on a smooth curve of the mesh or lines with the illumination source responsive to illumination of the surface damage. 19 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , wherein capturing images are created during gas turbine engine operational conditions selected from the group consisting of coasting, spool-up, and spool-down, including at least one complete revolution. 20 . The method for in-situ inspection of a gas turbine engine fan of claim 11 , wherein said sensor comprises at least one of, multiple sensors, a video camera, a high-speed camera, a CMOS sensor and a polarization camera.