Abstract: The entrance ends of a plurality of optical fibers are arranged in a circular array and each provided with light emitting material in the form of phosphor responsive to impingement of an electron beam. The circular array of the fiber optic entrance ends is scanned by an electron beam so that the light emitters are successively triggered, the time for light to travel the difference between successive light paths defined by the optical fibers corresponding to the time of scan from one light emitting phosphor to the next adjacent light emitting phosphor so that individual pulses of light exit from the ends of said fibers substantially simultaneously.

Abstract: The assembly includes a plurality of individual pulse lasers arranged to be successively triggered at predetermined time intervals. A single light transmissive body receives the output pulses from the lasers at different input angles so that the respective pulses follow different path lengths in the body. The sequence of firing of the lasers and the respective angles are such that pulses exiting from the body will all exit substantially simultaneously. The result is a high energy concentration of output light.

Abstract: A laser beam is scanned in a circular pattern so that it will successively impinge upon light entrance ends of a plurality of optical fibers arranged in a similar circular array. Successive fibers differ in path lengths in such a manner that the light from the scanning laser beam exits substantially simultaneously from the exit ends of the fibers so that a relatively high intensity or amplitude light pulse results.

Abstract: A steady light beam such as continuous wave, constant amplitude coherent light as provided by a laser, is moved through a given acute angle at a given frequency. The light beam is passed into a solid body of light transmissive material while moving through the given acute angle such that the initially received light in the body when the beam starts its movement through the acute angle follows a first path of a first given length before it emerges from the body. Subsequently received light in the body when the beam has completed its movement through the acute angle, in turn, follows a second path of a second given length different from the first given length before it emerges from the body. The referred-to-frequency is adjusted to define a time increment for the beam to move through the referred to given acute angle. This time increment is made substantially equal to the time it takes light to travel a path length in the body equal to the difference in the referred to first and second given lengths.