Abstract: The present invention contemplates to employ an eye-tracking device in an ophthalmic adaptive-optics system such that slow wavefront sensor and aberration-compensating element can be sufficient for the application. The present invention further contemplates to implement with the eye-tracking device a motion-compensating mechanism into the system such that the pupil images on both the wavefront sensor and the aberration-compensating element remain stationary during the operation of the system.

Abstract: The present invention contemplates a method and apparatus to generate a laser probe beam free of speckles. The present invention employs a holographic phase plate inserted in a laser beam path to modulate the relative phase across the beam. The holographic phase plate is designed to optimize the phase modulation across the beam while to minimize the degradation of the beam quality. The modulated laser beam has only a small and confined divergent angle and can then be refocused or collimated into a narrow and near collimated probe beam. The present invention further rotates the holographic phase plate to randomize the speckles in a time sequence. As a result, the probe beam preserves substantially the beam quality of a laser and produces substantially no speckles on image of its, intersection with a surface or material.

Abstract: The optical tracking device of the present invention is contemplated to obtain a large tracking range in an open loop configuration. The tracking device projects and scans two probe beams across a symmetric reference landmark that has at least two symmetric lines or axes. The two probe beams scan repeatedly and alternatively along two directions of which each is perpendicular to a symmetric line of the reference mark. For each scan, a substantially symmetric profile is generated in the scattered light as the beam scans across the boundary on each side of the symmetric reference. This symmetric profile in the scattered light is detected and used to determine the position of the related symmetric line. The position detection of the symmetric line is independent from the object's movement along the direction of the symmetric line. The scattered-light signal from the two probe beams is separated by synchronized detection in the time domain.

Abstract: The present invention contemplates a method and apparatus to generate a laser probe beam free of speckles. The present invention employs a holographic phase plate inserted in a laser beam path to modulate the relative phase across the beam. The holographic phase plate is designed to optimize the phase modulation across the beam while to minimize the degradation of the beam quality. The modulated laser beam has only a small and confined divergent angle and can then be refocused or collimated into a narrow and near collimated probe beam. The present invention further rotates the holographic phase plate to randomize the speckles in a time sequence. As a result, the probe beam preserves substantially the beam quality of a laser and produces substantially no speckles on image of its, intersection with a surface or material.

Abstract: The optical tracking device of the present invention is contemplated to obtain a large tracking range in an open loop configuration. The tracking device projects and scans two probe beams across a symmetric reference landmark that has at least two symmetric lines or axes. The two probe beams scan repeatedly and alternatively along two directions of which each is perpendicular to a symmetric line of the reference mark. For each scan, a substantially symmetric profile is generated in the scattered light as the beam scans across the boundary on each side of the symmetric reference. This symmetric profile in the scattered light is detected and used to determine the position of the related symmetric line. The position detection of the symmetric line is independent from the object's movement along the direction of the symmetric line. The scattered-light signal from the two probe beams is separated by synchronized detection in the time domain.