Abstract: A pulsed diode ring laser gyroscope and method of modulation are provided to greatly reduce the occurrence of frequency locking in optical gyroscopes at low rotational rates. One or two optical diodes serve as optical amplifiers for a pair of counterpropagating optical pulses circulating in an optical ring resonator. The amplifiers are driven twice each round trip (once for each pulse) using pulses much shorter than the round trip time. The short optical pulses overlap in regions of the resonator generally isolated from light scattering elements. The pulses are produced by gain switching the optical amplifiers with an electrical current pulse train having a fundamental period synchronous with the optical round trip time in the resonator cavity. With this modulation scheme, the diodes can be thought of as gates that open twice each round trip-once for each of the counterpropagating pulses. During each on time, the diodes amplify only a clockwise or counterclockwise pulse.

Abstract: A three-dimensional object is imaged by providing a coherent beam of light with a periodic variation in frequency and dividing the beam into a probe beam and a pump beam. The probe beam is directed toward the object, such that the frequency profile of the probe beam after reflection from the object is determined by the depth profile of the object. The pump beam and the reflected probe beam are directed into a nonlinear medium, such that two-wave mixing between the beams occurs in the medium, the two-wave mixing process causing the frequency profile of the probe beam to be converted to an intensity profile. The method may be further refined by adjusting the optical path length of the pump beam in order to adjust the accuracy range of the depth profile which is imaged.

Abstract: An apparatus for subtracting the amplitude of a first optical image on a first beam from the amplitude of a second optical image on a second beam includes a first beam splitter to divide the first beam into a first transmitted beam and a first reflected beam and to divide the second beam into a second transmitted beam and a second reflected beam. The first transmitted beam and the second reflected beam combine as a first mixed beam, while the first reflected beam and the second transmitted beam combine as a second mixed beam. A pinhole removes spatial information from the second mixed beam. The first and second mixed beams interfere within a nonlinear medium to create a composite hologram. A coherent reference beam directed at the nonlinear medium reads the interference pattern, so that the difference between the first and second images is superimposed on the reference beam emerging from the nonlinear medium.

Abstract: An optical fiber rotation sensor includes a source of coherent light and a first polarizing beam splitter for transmitting a first component of the coherent light having a first polarization direction and reflecting a second component of the coherent light having a second polarization direction orthogonal to the first polarization direction. A coiled multimode optical fiber is coupled to the first beam splitter with the first and second components propagating in the fiber in opposite directions. A polarizer transmits a linearly polarized third component containing equal contributions from the first and second components. A half-wave plate rotates the polarization of the third component by 45.degree.. A self-pumped phase conjugating element reflects a phase-conjugated fourth component such that the fourth component retraverses the half-wave plate and the polarizer, then is divided by the first polarizing beam splitter into fifth and sixth components propagating in the fiber in opposite directions.