Abstract: The invention discloses a method for sharing emotions within communication media using expressive 3D avatars. Users can create or import personalized 3D avatars that represent themselves (optional). The core functionality involves defining “emotion-mojis” by associating predefined animations and/or user-generated animations with specific emotions. These emotion-mojis can also include audio sounds for a richer emotional expression. During communication, users can select an emotion-mojis and initiate the playback of the corresponding animation (visual and/or audio) for their 3D avatar, allowing them to visually and/or audibly express their emotions to other participants. The invention further provides methods for automatic emotion detection through real-time analysis of user input (webcam video and microphone audio) to infer the user's emotional state and automatically play a corresponding emotion-moji.

Abstract: There is provided a MOMS sensor comprising a fiber interface comprising a fiber passthrough for one or more optical fibers, a cavity comprising an element hermetically encapsulated within the cavity, wherein the element is movably anchored by SiN arms, which are movable with respect to walls of the cavity, wherein the SiN arms comprise anchor portions at first ends of the SiN arms, which are connected to the element, and at second ends of the SiN arms, which are connected to the walls of the cavity, and the fiber interface is configured to receive the fibers through the fiber passthrough into positions for communications of light between the element and the fibers. In this way a robust structure that supports sensitivity of the sensor is provided.

Abstract: There is provided a MOMS sensor comprising a fiber interface comprising a fiber passthrough for one or more optical fibers, a cavity comprising an element hermetically encapsulated within the cavity, wherein the element is movably anchored by SiN arms, which are movable with respect to walls of the cavity, wherein the SiN arms comprise anchor portions at first ends of the SiN arms, which are connected to the element, and at second ends of the SiN arms, which are connected to the walls of the cavity, and the fiber interface is configured to receive the fibers through the fiber passthrough into positions for communications of light between the element and the fibers. In this way a robust structure that supports sensitivity of the sensor is provided.

Abstract: An illumination system includes a light source arranged for emitting non-collimated light towards a reflective surface of a scanning mirror assembly such that the light source occludes a region of the light reflected from the reflective surface. The scanning mirror assembly includes the reflective surface, which is arranged to be rotationally displaced around at least one rotation axis. The illumination system also includes an optical element for changing the propagation direction of the said reflected light so as to illuminate at least a part of the said occluded region.

Abstract: The present invention concerns a method for controlling a laser-based lighting system comprising a scanning mirror arrangement, arranged to be rotatable around two substantially orthogonal axes.

Abstract: The present invention concerns a lighting system, which comprises: a laser light source for radiating light; a wavelength conversion element for receiving the radiated light from the light source and for re-emitting wavelength converted white light; and a reflector element for reflecting the light received from the wavelength conversion element. The reflector element comprises a reflective surface and a micro-patterned surface comprising an array of micro-focal elements. Each of said micro-focal elements is configured to converge or diverge incident light from the wavelength conversion element.

Abstract: A micro-projection system for projecting light on a projection surface, comprising: —at least one coherent light source (101); —optical elements (102, 108, 109) in the optical path between said coherent light source and said projection surface; —said optical elements including at least one reflective member (102) actuated by a drive signal for deviating light from said light source so as to scan a projected image onto said projecting surface; —said optical elements including at least one vibrating element (102) actuated by a vibrating signal so as to reduce speckle onto said projecting surface. The corresponding method for reducing speckle is also provided.

Abstract: A micro scale includes one substrate forming a first zone constituting a first terminal, one conducting vibrating beam which has two opposite ends affixed on two supporting areas on the substrate, the conductive beam forming a second terminal; wherein the conductive beam is made of polymer gel having metallic microparticles in low quantity so as to avoid any contamination of a biological material to measure, the density of the metallic microparticles being high enough to achieve electrical conduction of the second terminal. A manufacturing process of such a micro scale circuit is also provided.

Abstract: A microresonator comprising a single-crystal silicon resonant element and at least one activation electrode placed close to the resonant element, in which the resonant element is placed in an opening of a semiconductor layer covering a substrate, the activation electrode being formed in the semiconductor layer and being level at the opening.

Abstract: A microresonator comprising a single-crystal silicon resonant element and at least one activation electrode placed close to the resonant element, in which the resonant element is placed in an opening of a semiconductor layer covering a substrate, the activation electrode being formed in the semiconductor layer and being level at the opening.

Abstract: A Light Modulating sensing MOSFET transistor includes: a substrate receiving light radiation, the substrate having two source and drain areas separated by a channel extending along a first direction; a gate conductive beam extending along a second direction being substantially perpendicular to the first direction, the beam being fixed at each of its two opposite ends on at least one supporting area and being located above the channel area, the gate beam being substantially opaque and flexible so as to perform progressive modulation of the light reaching the channel in accordance with its bending controlled by the difference of voltage between the gate and the bulk and causing the beam to bend and to come closer to the surface of the channel. A process for manufacturing a light Modulating sensing MOSFET transistor is also provided.

Abstract: A microresonator comprising a single-crystal silicon resonant element and at least one activation electrode placed close to the resonant element, in which the resonant element is placed in an opening of a semiconductor layer covering a substrate, the activation electrode being formed in the semiconductor layer and being level at the opening.