A steering wheel that includes optoelectronic components, each specific optoelectronic component including a light projector projecting light out of the steering wheel at two different angles, denoted a1 and a2, a light sensor detecting reflections of the light projected by neighboring optoelectronic components by an object above the steering wheel, a lens oriented relative to the light sensor such that the light sensor receives maximum intensity when light enters the lens at either of two particular angles, specifically, when light enters the lens at a particular angle b1, and at a particular angle b2 different than b1, wherein angle b1 views reflections of light projected at angle a1 by the optoelectronic component neighboring the specific optoelectronic component on one side, and angle b2 views reflections of light projected at angle a2 by the optoelectronic component neighboring the specific optoelectronic component on the side opposite the one side.

A steering wheel that includes optoelectronic components, each specific optoelectronic component including a light projector projecting light out of the steering wheel at two different angles, denoted a1 and a2, a light sensor detecting reflections of the light projected by neighboring optoelectronic components by an object above the steering wheel, a lens oriented relative to the light sensor such that the light sensor receives maximum intensity when light enters the lens at either of two particular angles, specifically, when light enters the lens at a particular angle b1, and at a particular angle b2 different than b1, wherein angle b1 views reflections of light projected at angle a1 by the optoelectronic component neighboring the specific optoelectronic component on one side, and angle b2 views reflections of light projected at angle a2 by the optoelectronic component neighboring the specific optoelectronic component on the side opposite the one side.

A steering wheel that includes optoelectronic components, each specific optoelectronic component including a light projector projecting light out of the steering wheel at two different angles, denoted a1 and a2, a light sensor detecting reflections of the light projected by neighboring optoelectronic components by an object above the steering wheel, a lens oriented relative to the light sensor such that the light sensor receives maximum intensity when light enters the lens at either of two particular angles, specifically, when light enters the lens at a particular angle b1, and at a particular angle b2 different than b1, wherein angle b1 views reflections of light projected at angle a1 by the optoelectronic component neighboring the specific optoelectronic component on one side, and angle b2 views reflections of light projected at angle a2 by the optoelectronic component neighboring the specific optoelectronic component on the side opposite the one side.

A steering wheel that includes optoelectronic components, each specific optoelectronic component including a light projector projecting light out of the steering wheel at two different angles, denoted a1 and a2, a light sensor detecting reflections of the light projected by neighboring optoelectronic components by an object above the steering wheel, a lens oriented relative to the light sensor such that the light sensor receives maximum intensity when light enters the lens at either of two particular angles, specifically, when light enters the lens at a particular angle b1, and at a particular angle b2 different than b1, wherein angle b1 views reflections of light projected at angle a1 by the optoelectronic component neighboring the specific optoelectronic component on one side, and angle b2 views reflections of light projected at angle a2 by the optoelectronic component neighboring the specific optoelectronic component on the side opposite the one side.

An image processing apparatus according to the present disclosure includes: a position detection illumination unit; an image recognition illumination unit; an illumination control unit; an imaging unit; and an image processing unit. The position detection illumination unit outputs position detection illumination light. The position detection illumination light is used for position detection on a position detection object. The image recognition illumination unit outputs image recognition illumination light. The image recognition illumination light is used for image recognition on an image recognition object. The illumination control unit controls the position detection illumination unit and the image recognition illumination unit to cause the position detection illumination light and the image recognition illumination light to be outputted at timings different from each other. The position detection illumination light and the image recognition illumination light enter the imaging unit at timings different from each other. The image processing unit determines switching between the position detection illumination light and the image recognition illumination light on the basis of luminance information regarding a captured image by the imaging unit. The image processing unit performs position detection on the position detection object on the basis of an imaging result of the imaging unit with the position detection illumination light switched on and performs image recognition on the image recognition object on the basis of an imaging result of the imaging unit with the image recognition illumination light switched on.

An image processing apparatus according to the present disclosure includes: a position detection illumination unit; an image recognition illumination unit; an illumination control unit; an imaging unit; and an image processing unit. The position detection illumination unit outputs position detection illumination light. The position detection illumination light is used for position detection on a position detection object. The image recognition illumination unit outputs image recognition illumination light. The image recognition illumination light is used for image recognition on an image recognition object. The illumination control unit controls the position detection illumination unit and the image recognition illumination unit to cause the position detection illumination light and the image recognition illumination light to be outputted at timings different from each other. The position detection illumination light and the image recognition illumination light enter the imaging unit at timings different from each other. The image processing unit determines switching between the position detection illumination light and the image recognition illumination light on the basis of luminance information regarding a captured image by the imaging unit. The image processing unit performs position detection on the position detection object on the basis of an imaging result of the imaging unit with the position detection illumination light switched on and performs image recognition on the image recognition object on the basis of an imaging result of the imaging unit with the image recognition illumination light switched on.

A portable device (100) comprising a controller (210), a memory (240), a camera (160) and a passive proximity sensor (170). The controller being configured for receiving input from said passive proximity sensor (170) indicating a light environment in front of the passive proximity sensor (170) detecting a change in light environment, determining a light pattern (P) of changes in light environment, determining if the light pattern (P) matches a stored initiating pattern, which is stored in the memory (240), and if so, accepting the light pattern (P) and in response thereto activating the camera (160), identifying an object (H) in front of the camera (160) and tracking the object (H) thereby enabling touchless gesture control of the portable device (100), characterized in that the passive proximity sensor is an ambient light sensor and the light pattern consists of a series of changes between dark and light (dark is light below a threshold, light is light above a second threshold).

A portable device (100) comprising a controller (210), a memory (240), a camera (160) and a passive proximity sensor (170). The controller being configured for receiving input from said passive proximity sensor (170) indicating a light environment in front of the passive proximity sensor (170) detecting a change in light environment, determining a light pattern (P) of changes in light environment, determining if the light pattern (P) matches a stored initiating pattern, which is stored in the memory (240), and if so, accepting the light pattern (P) and in response thereto activating the camera (160), identifying an object (H) in front of the camera (160) and tracking the object (H) thereby enabling touchless gesture control of the portable device (100), characterized in that the passive proximity sensor is an ambient light sensor and the light pattern consists of a series of changes between dark and light (dark is light below a threshold, light is light above a second threshold).

A projector includes: a pointer detecting unit that determines a type of each pointer; a coordinate calculating unit that calculates a pointed position of the pointer; a storage unit that stores a reference variation amount of the pointed position by the pointer for each of the pointers; and a projection control unit that acquires, from the storage unit, the reference variation amount according to the type of the pointer determined by the pointer detecting unit, and corrects, based on the acquired reference variation amount, the pointed position detected by the coordinate calculating unit.

A projector includes: a pointer detecting unit that determines a type of each pointer; a coordinate calculating unit that calculates a pointed position of the pointer; a storage unit that stores a reference variation amount of the pointed position by the pointer for each of the pointers; and a projection control unit that acquires, from the storage unit, the reference variation amount according to the type of the pointer determined by the pointer detecting unit, and corrects, based on the acquired reference variation amount, the pointed position detected by the coordinate calculating unit.