Active real-time characterization system

What is claimed is: 1 . A system for providing active real-time characterization of an article under test, comprising: an infrared light source for outputting a beam of coherent infrared light, the infrared light source configured to direct the beam of coherent infrared light at a particular area on the article under test; a first visible light source for outputting a first beam of coherent visible light, the first visible light source configured to direct the first beam of coherent visible light at the same particular area on the article under test; a visible light camera and a visible light second harmonic generation camera, the visible light camera and visible light second harmonic generation camera each configured to receive a first predetermined return beam of light from the particular area on the article under test; an infrared camera and an infrared second harmonic generation camera, the infrared camera and infrared second harmonic generation camera each configured to receive a second predetermined return beam of light from the particular area on the article under test; a sum frequency camera configured to receive a third return beam of light from the particular area on the article under test; and a processor coupled to receive signals from the visible light camera, the visible light second harmonic generation camera, the infrared camera, the infrared second harmonic generation camera and the sum frequency camera, the processor configured to calculate in real time a linear spectroscopic signal, a second harmonic generation spectroscopic signal and a sum-frequency spectroscopic signal, the processor also configured to compare each calculated signal with each other calculated signal and with a predetermined baseline signal to ensure that the article under test conforms to an expected value. 2 . The system of claim 1 , further comprising: a second visible light source for outputting a second beam of coherent visible light, the second visible light source configured to direct the second beam of coherent visible light at the same particular area on the article under test; a third order camera configured to receive a fourth return beam of light from the particular area on the article under test; and wherein the processor is also configured to calculate in real time a third order spectroscopic signal and to compare the third order spectroscopic signal with the other calculated signals and with a predetermined baseline signal to ensure that the article under test conforms to an expected value. 3 . The system of claim 1 , wherein each of the sources includes an intensity control for setting a predetermined intensity for the respective output beam of light. 4 . The system of claim 1 , wherein each of the sources includes a frequency control for setting a predetermined wavelength for the respective output beam of light. 5 . The system of claim 1 , wherein each of the sources includes a polarization control for setting a predetermined polarization for the respective output beam of light. 6 . The system of claim 1 , wherein each of the cameras includes an intensity control for setting a predetermined intensity for the respective input beam of light. 7 . The system of claim 1 , wherein each of the cameras includes a frequency control for setting a predetermined wavelength for the respective input beam of light. 8 . The system of claim 1 , wherein each of the cameras includes a polarization control for setting a predetermined polarization for the respective input beam of light. 9 . The system of claim 1 , further comprising a beam splitter configured to split a return beam of light into two portions, a first portion directed to the visible light camera and a second portion directed to the visible light second harmonic generation camera. 10 . A system for providing active real-time characterization of an article under test, comprising: an infrared light source for outputting a beam of coherent infrared light, the infrared light source configured to direct the beam of coherent infrared light at a particular area on the article under test; a first visible light source for outputting a first beam of coherent visible light, the first visible light source configured to direct the first beam of coherent visible light at the same particular area on the article under test; a visible light camera and a visible light second harmonic generation camera, the visible light camera and visible light second harmonic generation camera each configured to receive a first predetermined return beam of light from the particular area on the article under test; an infrared camera and an infrared second harmonic generation camera, the infrared camera and infrared second harmonic generation camera each configured to receive a second predetermined return beam of light from the particular area on the article under test; a third order camera configured to receive a third return beam of light from the particular area on the article under test; and a processor coupled to receive signals from the visible light camera, the visible light second harmonic generation camera, the infrared camera, the infrared second harmonic generation camera and the third order camera, the processor configured to calculate in real time a linear spectroscopic signal, a second harmonic generation spectroscopic signal and a third order spectroscopic signal, the processor also configured to compare each calculated signal with each other calculated signal and with a predetermined baseline signal to ensure that the article under test conforms to an expected value. 11 . The system of claim 10 , further comprising: a second visible light source for outputting a second beam of coherent visible light, the second visible light source configured to direct the second beam of coherent visible light at the same particular area on the article under test; a sum frequency camera configured to receive a fourth return beam of light from the particular area on the article under test; and wherein the processor is also configured to calculate in real time a sum frequency spectroscopic signal and to compare the sum frequency spectroscopic signal with the other calculated signals and with a predetermined baseline signal to ensure that the article under test conforms to an expected value. 12 . The system of claim 10 , wherein each of the sources includes an intensity control for setting a predetermined intensity for the respective output beam of light. 13 . The system of claim 10 , wherein each of the sources includes a frequency control for setting a predetermined wavelength for the respective output beam of light. 14 . The system of claim 10 , wherein each of the sources includes a polarization control for setting a predetermined polarization for the respective output beam of light. 15 . The system of claim 10 , wherein each of the cameras includes an intensity control for setting a predetermined intensity for the respective input beam of light. 16 . The system of claim 10 , wherein each of the cameras includes a frequency control for setting a predetermined wavelength for the respective input beam of light. 17 . The system of claim 10 , wherein each of the cameras includes a polarization control for setting a predetermined polarization for the respective input beam of light. 18 . The system of claim 10 , further comprising a beam splitter configured to split a return beam of light into two portions, a first portion directed to the visible light camera and a second portion directed to the visible