A system and a method for tracking a target and for compensating for atmospheric turbulence is described. In an embodiment, the system includes at least two light sources each emitting a light beam to the target; at least two collimators that collimate the light beam of the associated light source; and a reference device to reflect a portion of the light beam exiting from all the collimators. The system also includes: at least two targeting modules to lead the light beam from the light source to reach a predetermined zone of the target; at least two detection modules to receive and detect the portion of the beam reflected by the reference device; a module for determining angle of deviation; a module for determining phase deviation; and an adjustment module for adjusting each of the light sources in order to compensate for atmospheric turbulence.

A system and a method for tracking a target and for compensating for atmospheric turbulence is described. In an embodiment, the system includes at least two light sources each emitting a light beam to the target; at least two collimators that collimate the light beam of the associated light source; and a reference device to reflect a portion of the light beam exiting from all the collimators. The system also includes: at least two targeting modules to lead the light beam from the light source to reach a predetermined zone of the target; at least two detection modules to receive and detect the portion of the beam reflected by the reference device; a module for determining angle of deviation; a module for determining phase deviation; and an adjustment module for adjusting each of the light sources in order to compensate for atmospheric turbulence.

An example apparatus includes a light projecting system, a light receiving system, and a controller. The light projecting system projects beams of light of a wavelength that is invisible. The beams form a pattern on a surface when the beams are incident upon the surface. The light receiving system acquires an image of the pattern on the surface. The controller calculates a distance to the surface based on the image. The light receiving system includes a lens, an imaging sensor, and a bandpass filter. The imaging sensor includes a first subset of photodetectors sensitive to wavelengths of light that are visible and a second subset of photodetectors sensitive to the wavelength of light that is invisible. The bandpass filter includes a first passband whose range corresponds to the wavelengths of light that are visible and a second passband whose range corresponds to the wavelength of light that is invisible.

An example apparatus includes a light projecting system, a light receiving system, and a controller. The light projecting system projects beams of light of a wavelength that is invisible. The beams form a pattern on a surface when the beams are incident upon the surface. The light receiving system acquires an image of the pattern on the surface. The controller calculates a distance to the surface based on the image. The light receiving system includes a lens, an imaging sensor, and a bandpass filter. The imaging sensor includes a first subset of photodetectors sensitive to wavelengths of light that are visible and a second subset of photodetectors sensitive to the wavelength of light that is invisible. The bandpass filter includes a first passband whose range corresponds to the wavelengths of light that are visible and a second passband whose range corresponds to the wavelength of light that is invisible.

An electronic device includes a first chip, a second chip bonded to the first chip with a bump, a first metal pattern provided on a first surface that is a surface of the first chip facing the second chip, and a second metal pattern provided on a second surface that is a surface of the second chip facing the first chip. The first chip has a first transmission region. A transmittance for light of the first transmission region is higher than a transmittance of a region other than the first transmission region in the first chip. The first metal pattern and the second metal pattern overlap the first transmission region in a thickness direction of the first chip and the second chip. The second metal pattern is located outside the first metal pattern in a direction in which the first surface and the second surface extend.

An electronic device includes a first chip, a second chip bonded to the first chip with a bump, a first metal pattern provided on a first surface that is a surface of the first chip facing the second chip, and a second metal pattern provided on a second surface that is a surface of the second chip facing the first chip. The first chip has a first transmission region. A transmittance for light of the first transmission region is higher than a transmittance of a region other than the first transmission region in the first chip. The first metal pattern and the second metal pattern overlap the first transmission region in a thickness direction of the first chip and the second chip. The second metal pattern is located outside the first metal pattern in a direction in which the first surface and the second surface extend.

Disclosed is a method and a system for retrieving a location of a base point of a wheeled vehicle in a local coordinate system of a tridimensional sensor mounted on the vehicle. The method includes acquiring point cloud frames while the wheeled vehicle is moving along a straight path and a curved path and a point cloud representative of a portion of the vehicle, computing a main direction vector, a main direction line and a location of an instantaneous centre of rotation of the wheeled vehicle in the local coordinate system, and retrieving the location of the base point.

Disclosed is a method and a system for retrieving a location of a base point of a wheeled vehicle in a local coordinate system of a tridimensional sensor mounted on the vehicle. The method includes acquiring point cloud frames while the wheeled vehicle is moving along a straight path and a curved path and a point cloud representative of a portion of the vehicle, computing a main direction vector, a main direction line and a location of an instantaneous centre of rotation of the wheeled vehicle in the local coordinate system, and retrieving the location of the base point.

The present invention relates to an ultrasound-based system for localizing a medical device within the field of view of an ultrasound imaging probe. A localization system is provided that includes at least three ultrasound emitters that are arranged on a frame; and a position triangulation unit. The frame is adapted for attachment to an ultrasound imaging probe. The position triangulation unit determines a spatial position of the ultrasound detector relative to the at least three ultrasound emitters based on signals received from an ultrasound detector that is attached to the medical device. The frame includes a detachable reference volume comprising a background volume and an inclusion or void. When the detachable reference volume is attached to the frame and the frame is attached to the ultrasound imaging probe the inclusion or void provides a corresponding image feature within the field of view of the ultrasound imaging probe for use in calibrating the field of view of the ultrasound imaging probe with the coordinate system of the localization system.

Embodiments use holographic projection in augmented reality to visualize a building in 3D and show, as a holographic figure, the position of personnel in the building. In some embodiments, a user can “tap” on a holographic figure to view data on that person, such as skin temperature, room temperature, heart rate, etc.