Method and apparatus for controlling light output intensity and protection from high intensity light

What is claimed is: 1. An apparatus for viewing a surface, the apparatus comprising: an examining instrument having an imaging path through which the surface is observed; a Xenon light source illuminating the surface; an imager detecting light reflected from the surface, and generating image signals representative of light reflected from the surface; a camera control unit (CCU) processing the image signals; and a controller associated with the imager and the CCU, the controller processing the image signals, the controller including software executing on the controller, the software executing on the controller decrementing or incrementing an output intensity of the Xenon light source via at least two steps, wherein the intensity of the at least two steps is incremented or decremented by a predetermined percentage of a maximum output intensity of the Xenon light source; wherein the controller is adapted to detect a potential safety issue and, if a potential safety issue is detected, to increment or decrement an output intensity of the Xenon light source via the software executing on the controller, the software executing on the controller incrementing the output intensity of the Xenon light source with a specified step ΔP scan , from P scan,min to P max , where P scan,min is less than P max , and P max is a maximum allowed output intensity of the Xenon light source; and wherein the controller is further adapted to compute, during the incrementing, a correlation metric indicative of a correlation between a measured achromatic image brightness (Luma meas ), on Image Motion Metrics or Perimeter Black, and the output intensity of the Xenon light source, within a specified step, and to set the output intensity of the Xenon light source to a safe level, if a correlation between the measured achromatic image brightness and the incrementing output intensity of the Xenon light source is not detected. 2. The apparatus of claim 1 , further comprising a communication bus coupled to a plurality of bus interfaces for communication between the Xenon light source and the CCU. 3. The apparatus of claim 1 , wherein the Xenon light source has at least one of high-frequency noise, slow-response time, nonlinearity, and non-monotonic response time. 4. The apparatus of claim 1 , wherein the examining instrument is selected from a group consisting of an endoscope, laryngoscope, bronchoscope, fiberscope, duodenoscope, gastroscope, flexible endoscope, arthroscope, cystoscope, laparoscope, anoscope, and sigmoidoscope. 5. The apparatus of claim 1 , wherein the imager is either located distally inside the examining instrument, proximately inside the examining instrument, or externally from the examining instrument. 6. The apparatus of claim 1 , wherein the imager is a CCD or CMOS imager. 7. A method for controlling a Xenon light source in an apparatus configured to view a surface, the method comprising: incrementing or decrementing an output intensity of the Xenon light via at least two steps by a predetermined percentage of a maximum output intensity of the Xenon light source; detecting a potential safety issue and, if a potential safety issue is detected, incrementing the output intensity of the Xenon light source with a specified step ΔP scan , from P scan,min to P max , where P scan,min is less than P max , and where P max is a maximum allowed output intensity of the Xenon light source; and computing, during the incrementing, a correlation-metric indicative of a correlation between a measured achromatic image brightness (Luma meas ), on Image Motion Metrics or Perimeter Black, and the output intensity of the Xenon light source, within a specified step, and setting the output intensity to a safe level, if a correlation between the measured achromatic image brightness and the incrementing output intensity of the Xenon light source is not detected.