A scanning optical system, includes a mirror unit equipped with a first mirror surface and a second mirror surface each of which inclines to a rotation axis; and a light projecting system which includes at least one light source to emit a light flux toward the first mirror surface. A light flux emitted from the light source is reflected on the first mirror surface of the mirror unit, thereafter, reflected on the second mirror surface, and then, projected so as to scan in a main scanning direction onto an object in accordance with rotation of the mirror unit, and in a case where a direction included in a main scanning plane is set to 0 degree, the light flux reflected on the second mirror surface is polarized in a range within an angle of 30 degrees to the main scanning plane.

An optical scanning apparatus includes a light source, a deflector, an optical member, a supporting portion, a casing, a cover member, a first air current deflecting portion configured to deflect, to a direction from the bottom toward the cover member, an air current generated by rotation of the rotatable polygonal mirror and flowing along a longitudinal direction of the optical member; and a second air current deflecting portion provided on the cover member and configured to deflect, to a direction crossing the longitudinal direction, the air current deflected by the first air current deflecting portion and flowing in the longitudinal direction.

A system and method for marking a moving surface of a fiber optic cable is provided. The system includes a supply of the fiber optic cable, a laser generating device configured to generate a laser beam that forms markings by interacting with the material of the moving surface of the fiber optic cable. The system includes a movement device moving the fiber optic cable through the system at a speed of at least 50 m per minute. The system includes a laser directing device located in the path of the laser beam and configured to change the path of the laser beam to direct the laser beam to a plurality of discrete locations on the moving surface to form a series of marks on the moving surface. The moving surface includes a plurality of tracking indicia to allow the position of the moving surface to be determined.

An optical scanning apparatus includes a light source, a deflector, an optical member, a supporting portion, a casing, a cover member, a first air current deflecting portion configured to deflect, to a direction from the bottom toward the cover member, an air current generated by rotation of the rotatable polygonal mirror and flowing along a longitudinal direction of the optical member; and a second air current deflecting portion provided on the cover member and configured to deflect, to a direction crossing the longitudinal direction, the air current deflected by the first air current deflecting portion and flowing in the longitudinal direction.

A light reflection device includes a reflection member having a reflection surface that is formed in a planar shape. The reflection surface reflects incident light. The reflection member performs a revolution and a rotation simultaneously. A direction of the revolution of the reflection member and a direction of the rotation of the reflection member are the same. Angular velocity of the revolution of the reflection member is equal to twice angular velocity of the rotation of the reflection member.

An optical scanning device that scans incident light by causing a mirror to oscillate is provided. The optical scanning device includes a displacement sensor for detecting a swing angle of the mirror and a temperature sensor used for temperature compensation of the displacement sensor. The displacement sensor is a piezoelectric sensor that has a structure in which a lower electrode, a piezoelectric film, and an upper electrode are layered in this order. The temperature sensor is a resistance type temperature measuring body that has a same layer structure as the lower electrode.

An apparatus include a motor, a first scanner, and a second scanner. The first scanner is coupled to the motor, and the motor is configured to rotate the first scanner at a first angular velocity about a rotation axis to deflect a first beam incident in a third plane on the first scanner into a first plane different from the third plane. The second scanner is coupled to the motor, and the motor is configured to rotate the second scanner at a second angular velocity different from the first angular velocity about the rotation axis to deflect a second beam incident in the third plane on the second scanner into a second plane different from the third plane.

A LIDAR system comprising a multi-polygon scanner assembly, a first beam forming element comprising a plurality of optically-reflective beam switching surfaces and spaced-apart apertures, a second beam steering element and beam guide mirror assembly configured to provide complete beam scan utilization with no scanning dead period.

Aspects of the present disclosure provide light detection and ranging (LIDAR) systems and methods for changing or adjusting field of view (FOV) during operation. Changing the FOV may include transmitting an optical beam toward a target, and forming the FOV using the optical beam via a first rotating reflector and a second rotating reflector. The first rotating reflector may include a galvo mirror in control of the vertical FOV, and the second rotating reflector may include a rotating polygon mirror in control of and providing for the horizontal FOV. The FOV may be adjusted in the vertical direction by actuating the first rotating reflector along a vertical direction using a first actuator. The first actuator may determine the actuation based on an orientation of the LIDAR system (e.g., a difference between an initial orientation measured after installation and a baseline orientation referencing a horizontal orientation).

A scanning lidar has an illumination source comprising a plurality of lasers and a mirror system. The mirror system reflects light from the illumination source into an environment within a field of view. The mirror system includes a mirror arranged to rotate to reflect light from the illumination source to scan light from the plurality of lasers horizontally within the field of view of the system. The mirror system reflects light from the illumination source to position light, in discrete vertical steps, from the plurality of lasers vertically within the field of view.