Eye safety protection system for a laser transmission system wherein laser energy scattered back along the beam path is detected

1. An eye safety protection system for a laser transmission system, said system comprising:

• a housing having a top, bottom, a forward end with an opening and an enclosed rear end;
  
  an optical element covering said opening;
  
  laser transmission unit located within said housing, wherein said laser transmission unit has a longitudinal axis parallel with the housing top;
  
  a laser beam optical path defined as the central, longitudinal axis of the laser transmission unit extending from said unit and protruding through the housing forward end opening optical element for projection of a laser beam from said laser transmission unit to an object, wherein the laser beam generated by the laser transmission unit proceeds along the optical path through the housing front optical element to said object, striking the object, wherein a portion of the energy from said laser beam is scattered, some of said scattered energy bouncing off said object back along the laser beam optical axis toward the laser transmission unit within the housing;
  
  a beam splitter positioned between the laser transmission unit and the housing forward end opening in the laser beam optical path, said beam splitter being comprised of a mirror positioned at an angle to the optical path, said mirror having a central portion through which the laser beam optical axis passes, an inner surface defined as that surface generally facing the laser transmission unit and an outer surface defined as that surface generally facing the housing forward end opening, wherein said mirror outer surface is adapted to reflect a portion of the scattered energy incident on it;
  
  a detector for receiving the reflected scattered energy from said beam splitter mirror outer surface, said detector being a photoelectric device which converts the reflected scattered energy to a voltage output signal;
  
  an amplifier and filter unit electrically connected to said detector for receiving and treating said voltage output signal; and
  
  a comparator and regulation unit electrically connected to said amplifier and filter unit for receiving said treated voltage output signal and electrically connected to said laser transmission unit for controlling the amount of power in said laser beam, wherein said treated signal is compared to the original laser beam frequency to determine whether the reflected scattered energy has the same frequency as the laser beam, and the amplitude of said treated signal is compared with preset levels for increasing or lowering the amount of power in said laser beam.