The present invention is directed to a user-operated spotlight system and method for lighting a performer on a stage or performance space; the user-operated spotlight system comprising a screen which displays an image of the stage and a cursor, a screen cursor positioner adapted to be operated to move the cursor on the screen, a processor connected to the screen, and, a plurality of controllable spotlights which are connected to the processor and which plurality of controllable spotlights can be moved by a user moving the cursor on the screen. The advantage of providing such a user-operated spotlight system is that a single user can operate a plurality of spotlights.

A virtual image generation system comprises a planar optical waveguide having opposing first and second faces, an in-coupling (IC) element configured for optically coupling a collimated light beam from an image projection assembly into the planar optical waveguide as an in-coupled light beam, a first orthogonal pupil expansion (OPE) element associated with the first face of the planar optical waveguide for splitting the in-coupled light beam into a first set of orthogonal light beamlets, a second orthogonal pupil expansion (OPE) element associated with the second face of the planar optical waveguide for splitting the in-coupled light beam into a second set of orthogonal light beamlets, and an exit pupil expansion (EPE) element associated with the planar optical waveguide for splitting the first and second sets of orthogonal light beamlets into an array of out-coupled light beamlets that exit the planar optical waveguide.

A virtual image generation system comprises a planar optical waveguide having opposing first and second faces, an in-coupling (IC) element configured for optically coupling a collimated light beam from an image projection assembly into the planar optical waveguide as an in-coupled light beam, a first orthogonal pupil expansion (OPE) element associated with the first face of the planar optical waveguide for splitting the in-coupled light beam into a first set of orthogonal light beamlets, a second orthogonal pupil expansion (OPE) element associated with the second face of the planar optical waveguide for splitting the in-coupled light beam into a second set of orthogonal light beamlets, and an exit pupil expansion (EPE) element associated with the planar optical waveguide for splitting the first and second sets of orthogonal light beamlets into an array of out-coupled light beamlets that exit the planar optical waveguide.

The invention relates to an opto-mechanical scanning device (100) arranged for deflecting an incident light beam (191). The scanning device comprises first and second reflective surfaces (M1, M2), a transparent, deformable, non-fluid body (110) having a refractive index which is greater than the refractive index of air, an actuator system (120) arranged to move the first reflective surface (M1) so that an angle of the first reflective surface (M1) is adjustable, a first window (131) arranged to receive and transmit the at least one incident light beam into the non-fluid body, a second window (132) arranged to receive and transmit the at least one incident light beam out of the non-fluid body. The first and second windows are arranged adjacent to the non-fluid body with the second reflective surface (M2) arranged so that the incident light beam can be transmitted out of the non-fluid body after being reflected successively by the first and second reflective surfaces.

A mirror unit 2 includes a mirror device 20 including a base 21 and a movable mirror 22, an optical function member 13, and a fixed mirror 16 that is disposed on a side opposite to the mirror device 20 with respect to the optical function member 13. The mirror device 20 is provided with a light passage portion 24 that constitutes a first portion of an optical path between the beam splitter unit 3 and the fixed mirror 16. The optical function member 13 is provided with a light transmitting portion 14 that constitutes a second portion of the optical path between the beam splitter unit 3 and the fixed mirror 16. A second surface 21b of the base 21 and a third surface 13a of the optical function member 13 are joined to each other.

An apparatus comprising: a thermally-actuated microactuator configured to deflect a component in dependence on an applied stimulus; and an extender having a length configured to increase deflection of the component by the microactuator, wherein the extender comprises one or more voids.

The disclosed subject matter relates to a method of manufacturing a light projector module, comprising the steps of: providing a base plate, a light source on the base plate, and a micro-electro-mechanical-system (MEMS) scanning assembly, wherein the base plate has, between the light source and the MEMS scanning assembly, a mounting surface accessible at one side of the base plate; positioning a set of one or more lenses on the mounting surface and adjusting the position of the one or more lenses of the set while the light source is emitting and at least one light beam projected by the light projector module is monitored in a display area; and mounting the one or more lenses of the set in the adjusted position fixedly on the base plate.

Techniques to be described herein are based upon the combination of a digital lock-in amplifier approach with a numerical method to yield accurate estimations of the amplitude and phase of a sense signal obtained from a movement sensor associated with a resonant MEMS device such as a MEMS mirror. The techniques described herein are efficient from a computational point of view, in a manner which is suitable for applications in which the implementing hardware is to follow size and power consumption constraints.

A MEMS device includes: a first beam and a second beam that are symmetrically disposed with respect to a first rotation axis of a mirror portion, in which a third beam is disposed on a side opposite to the first beam and the second beam with reference to a line that is orthogonal to the first rotation axis and passes through a center of gravity of the mirror portion.

An optical reflector element includes: a first oscillator and a second oscillator for oscillating a reflector and disposed with the reflector being interposed therebetween along a first axis; and a third oscillator for oscillating the first oscillator and the second oscillator. The third oscillator includes: a first assister that causes the support of the first oscillator and the support of the second oscillator to operate, by connecting the support of the first oscillator and the support of the second oscillator to one base included in a pair of bases disposed with the first axis being interposed therebetween; and a second assister that causes the support of the first oscillator and the support of the second oscillator to operate, by connecting the support of the first oscillator and the support of the second oscillator to an other base included in the pair of bases.