A method for gesture detection comprises pre-processing and main-processing steps, wherein the pre-processing comprises emitting light using a light emitting device and generating of directional sensor signals as a function of time by detecting a fraction of the emitted light reflected by means of a movable object using a directional light sensor array). The main-processing comprises calculating coordinates as a function of time by using the directional sensor signals, being indicative of a position of the object with reference to a plane parallel to a principal plane of the light sensor array, and detecting a movement of the object depending on the timing of the coordinates.

Disclosed is an operation display device, including: a display unit; a touch panel to simultaneously detect touch operations carried out with fingers to a display surface of the display unit; a finger shape detecting unit to detect a shape of a contact part of the finger, which contacts to the display surface in each of the touch operations; and a control unit to control display contents of the display unit, wherein when the touch operations are simultaneously detected by the touch panel, the control unit judges whether the touch operations are an operation carried out by one operator or are operations carried out by a plurality of operators in accordance with the shape of the contact part of the finger relating to each touch operation, and changes the display contents of the display unit in accordance with a result of judging the touch operations.

Embodiments of an apparatus and system are described for a hybrid computing device. Some embodiments may comprise a computing device having an enclosure arranged to support a display on a front of the enclosure, a projector adjustment ring integrated into a portion of the perimeter of the enclosure, and a projector module adjustably coupled to the projector adjustment ring. In various embodiments, the projector module may be arranged for dual-axis rotation within the projector adjustment ring. Other embodiments are described and claimed.

Embodiments of an apparatus and system are described for a hybrid computing device. Some embodiments may comprise a computing device having an enclosure arranged to support a display on a front of the enclosure, a projector adjustment ring integrated into a portion of the perimeter of the enclosure, and a projector module adjustably coupled to the projector adjustment ring. In various embodiments, the projector module may be arranged for dual-axis rotation within the projector adjustment ring. Other embodiments are described and claimed.

A fabric-based item may include a housing that is covered in fabric. Areas of the fabric may overlap input circuitry such as button switches, touch sensors, force sensors, proximity sensors, and other sensing circuitry and may overlap other components such as light-emitting components and haptic output devices. The fabric-based item may include control circuitry that gathers user input from the input circuitry and wireless communications circuitry that the control circuitry uses to transmit remote control commands and other wireless signals in response information from the input circuitry. The fabric-based item may have a weight that is located in the housing to orient the housing in a desired direction when the housing rests on a surface. A movable weight may tilt the housing in response to proximity sensor signals or other input. Portions of the fabric may overlap light-emitting components and optical fiber configured to emit light.

A fabric-based item may include a housing that is covered in fabric. Areas of the fabric may overlap input circuitry such as button switches, touch sensors, force sensors, proximity sensors, and other sensing circuitry and may overlap other components such as light-emitting components and haptic output devices. The fabric-based item may include control circuitry that gathers user input from the input circuitry and wireless communications circuitry that the control circuitry uses to transmit remote control commands and other wireless signals in response information from the input circuitry. The fabric-based item may have a weight that is located in the housing to orient the housing in a desired direction when the housing rests on a surface. A movable weight may tilt the housing in response to proximity sensor signals or other input. Portions of the fabric may overlap light-emitting components and optical fiber configured to emit light.

Disclosed herein is a projection type image display apparatus, including: a projecting portion projecting an input image on an image projected body; a camera portion photographing the image projected body; a display control block controlling display of a projected image projected by the projecting portion; and a gesture recognizing unit recognizing a gesture manipulation of a user contained in the image photographed by the camera portion.

An operating device having an optical finger navigation module for installation in a steering wheel of a motor vehicle, which allows for secure operation and can be produced at low cost, is disclosed. The operating device has a mounting frame, in which a first light guiding element and the optical finger navigation module is held by a light sealing element. The light sealing element is mounted by a snap connection on the mounting frame. The mounting frame has at least one guide element with which a movement of the mounting frame can be guided.

A touch sensing apparatus is provided comprising: a light transmissive panel that defines a touch surface, a plurality of light emitters and detectors arranged along a perimeter of the light transmissive panel, a plurality of optical components arranged along the perimeter of the light transmissive panel, wherein the light emitters are arranged to emit a respective beam of emitted light and the optical components are configured to direct the emitted light to a path across the light transmissive panel. Optionally, optical components comprise a light guide arranged to receive light from the light emitters through a first surface and couple out light travelling in the light guide to the touch surface through a second surface. The second surface may be diffusively transmissive. The light guide may further comprise a reflective surface configured to internally reflect light travelling in the light guide from the first surface to the diffusive surface. The reflective surface may be diffusely reflective, partially diffusely reflective, or specularly reflective.

Disclosed is a lighting assembly (10) that includes a mounting surface (14) that that allows the installer to attach the assembly to an external structure (15) with an adhesive strip (144). The lighting assembly also includes a light-emitting surface (18) that directs spot illumination to a predetermined display area (17) by way of a combination of collimated light-emitting elements (182) and an optical element (184). The lighting assembly also features a touch-sensitive surface (16) that allows the user to both program the lighting assembly and control the display lighting in a flexible manner by providing the user with different modes of interacting with the lighting assembly.