An apparatus for intraoral imaging has an intraoral camera that defines a field of view with a first dimension and a second dimension orthogonal to the first dimension. A projector has a laser diode energizable to emit a light beam; a collimator in the path of the emitted light beam; first beam-shaping optics disposed to shape the collimated light beam in the second dimension to form a linear light pattern; focusing optics disposed to focus the shaped collimated beam at a focal plane; and a scanner that is disposed substantially at the focal plane and that is energizable to scan the formed linear light pattern along the second dimension to successive positions of the field of view. A control logic processor coordinates energizing the laser diode and scanner with image capture by the intraoral camera.

An apparatus for intraoral imaging has an intraoral camera that defines a field of view with a first dimension and a second dimension orthogonal to the first dimension. A projector has a laser diode energizable to emit a light beam; a collimator in the path of the emitted light beam; first beam-shaping optics disposed to shape the collimated light beam in the second dimension to form a linear light pattern; focusing optics disposed to focus the shaped collimated beam at a focal plane; and a scanner that is disposed substantially at the focal plane and that is energizable to scan the formed linear light pattern along the second dimension to successive positions of the field of view. A control logic processor coordinates energizing the laser diode and scanner with image capture by the intraoral camera.

The invention discloses a parabolic LED lamp, comprises a lamp body, a lamp base, an arc lens, a parabolic reflective cup, an LED light source, and a drive; wherein the parabolic reflective cup is embedded and installed in the lamp body; the LED light source is installed in the bottom of the parabolic reflective cup and toward to the arc lens; the drive internally configured in the lamp body connects the lamp base and the LED light source; the inner wall of the arc lens is formed with a plurality of first lens areas and second lens areas spaced apart, the first lens areas uniformly distributed with a plurality of small hexagonal lenses with a same specifications, the second lens areas uniformly distributed with a plurality of small rhombic lenses with a same specifications.

The invention discloses a parabolic LED lamp, comprises a lamp body, a lamp base, an arc lens, a parabolic reflective cup, an LED light source, and a drive; wherein the parabolic reflective cup is embedded and installed in the lamp body; the LED light source is installed in the bottom of the parabolic reflective cup and toward to the arc lens; the drive internally configured in the lamp body connects the lamp base and the LED light source; the inner wall of the arc lens is formed with a plurality of first lens areas and second lens areas spaced apart, the first lens areas uniformly distributed with a plurality of small hexagonal lenses with a same specifications, the second lens areas uniformly distributed with a plurality of small rhombic lenses with a same specifications.

A luminaire module includes a light source located in a first plane and a truncated optical system having an optical axis. The truncated optical system is configured to focus and aim light from the light source to form an output beam. The module also controls a tilt angle of the output beam over a range of tilt angles by adjusting a position of the optical system relative to a position of the light source in a plane perpendicular to the optical axis. The spatial extent of the optical system is constrained to the minimum dimensions required in order to focus and aim substantially all of the light from the light source over a predetermined range of tilt angles for the output beam. A pan angle of the output beam can also be adjusted, such as by rotating the luminaire module. Tilt and/or pan may be manual or motorized and controlled by a control system. Multiple such luminaire modules may be combined.

A luminaire module includes a light source located in a first plane and a truncated optical system having an optical axis. The truncated optical system is configured to focus and aim light from the light source to form an output beam. The module also controls a tilt angle of the output beam over a range of tilt angles by adjusting a position of the optical system relative to a position of the light source in a plane perpendicular to the optical axis. The spatial extent of the optical system is constrained to the minimum dimensions required in order to focus and aim substantially all of the light from the light source over a predetermined range of tilt angles for the output beam. A pan angle of the output beam can also be adjusted, such as by rotating the luminaire module. Tilt and/or pan may be manual or motorized and controlled by a control system. Multiple such luminaire modules may be combined.

The invention discloses a parabolic LED lamp, comprises a lamp body, a lamp base, an arc lens, a parabolic reflective cup, an LED light source, and a drive; wherein the parabolic reflective cup is embedded and installed in the lamp body; the LED light source is installed in the bottom of the parabolic reflective cup and toward to the arc lens; the drive internally configured in the lamp body connects the lamp base and the LED light source; the inner wall of the arc lens is formed with a plurality of first lens areas and second lens areas spaced apart, the first lens areas uniformly distributed with a plurality of small hexagonal lenses with a same specifications, the second lens areas uniformly distributed with a plurality of small rhombic lenses with a same specifications.

The invention discloses a parabolic LED lamp, comprises a lamp body, a lamp base, an arc lens, a parabolic reflective cup, an LED light source, and a drive; wherein the parabolic reflective cup is embedded and installed in the lamp body; the LED light source is installed in the bottom of the parabolic reflective cup and toward to the arc lens; the drive internally configured in the lamp body connects the lamp base and the LED light source; the inner wall of the arc lens is formed with a plurality of first lens areas and second lens areas spaced apart, the first lens areas uniformly distributed with a plurality of small hexagonal lenses with a same specifications, the second lens areas uniformly distributed with a plurality of small rhombic lenses with a same specifications.

A vehicle lighting fixture can form a predetermined light distribution pattern at a position horizontally or vertically shifted with respect to a reference position. The vehicle lighting fixture include: a light source; an optical deflector configured to include a mirror part; a rotary reflecting member configured to reflect light having been reflected by the mirror part of the optical deflector; a screen member configured to form a luminance distribution by the light reflected by the rotary reflecting member; an optical system configured to project the luminance distribution formed in the screen member to form the predetermined light distribution pattern; and a rotary control unit configured to control the rotary reflecting member to form the luminance distribution at a reference position or a position shifted with respect to the reference position. The rotary control unit can control any of the rotational direction and the rotational amount of the rotary reflecting member.

A vehicle lighting fixture can form a predetermined light distribution pattern at a position horizontally or vertically shifted with respect to a reference position. The vehicle lighting fixture include: a light source; an optical deflector configured to include a mirror part; a rotary reflecting member configured to reflect light having been reflected by the mirror part of the optical deflector; a screen member configured to form a luminance distribution by the light reflected by the rotary reflecting member; an optical system configured to project the luminance distribution formed in the screen member to form the predetermined light distribution pattern; and a rotary control unit configured to control the rotary reflecting member to form the luminance distribution at a reference position or a position shifted with respect to the reference position. The rotary control unit can control any of the rotational direction and the rotational amount of the rotary reflecting member.