A method for operating a hand-held material investigation device includes transmitting a measurement signal into an object under investigation, and acquiring a position of the material investigation device in relation to a surface of the object under investigation in order to determine a material property of a region, concealed behind the surface, of the object under investigation in a space-resolved and/or direction-resolved manner. The method further includes displaying the material property as at least one digital display object with a physical display unit, and displaying additional measurement information with the same at least one digital display object by way of color coding of the at least one digital display object.

A method for operating a hand-held material investigation device includes transmitting a measurement signal into an object under investigation, and acquiring a position of the material investigation device in relation to a surface of the object under investigation in order to determine a material property of a region, concealed behind the surface, of the object under investigation in a space-resolved and/or direction-resolved manner. The method further includes displaying the material property as at least one digital display object with a physical display unit, and displaying additional measurement information with the same at least one digital display object by way of color coding of the at least one digital display object.

An athletic performance monitoring system, including a gesture recognition processor configured to execute gesture recognition processes. Interaction with the athletic performance monitoring system may be based, at least in part, on gestures performed by a user, and may offer an alternative to making selections on the athletic performance monitoring system using physical buttons, which may be cumbersome and/or inconvenient to use while performing an athletic activity. Additionally, recognized gestures may be used to select one or more operational modes for the athletic performance monitoring system, such that a reduction in power consumption may be achieved.

An athletic performance monitoring system, including a gesture recognition processor configured to execute gesture recognition processes. Interaction with the athletic performance monitoring system may be based, at least in part, on gestures performed by a user, and may offer an alternative to making selections on the athletic performance monitoring system using physical buttons, which may be cumbersome and/or inconvenient to use while performing an athletic activity. Additionally, recognized gestures may be used to select one or more operational modes for the athletic performance monitoring system, such that a reduction in power consumption may be achieved.

Disclosed is an electronic device. The electronic device includes a first housing, a second housing, and an input-output assembly. The second housing is arranged on a side opposite to a display screen of the electronic device. The first housing and the second housing are connected to define a receiving space. The second housing defines a light through hole. The input/output assembly is arranged on the first housing and received in the receiving space. A side of the first housing facing the second housing is arranged with a limiting member, and the limiting member is configured to fix the input-output assembly on the first housing. The input-output assembly includes a plurality of input-output modules including a laser transmitter, a laser receiver, and at least one image collector. Each input-output module faces the light through hole.

Disclosed is an electronic device. The electronic device includes a first housing, a second housing, and an input-output assembly. The second housing is arranged on a side opposite to a display screen of the electronic device. The first housing and the second housing are connected to define a receiving space. The second housing defines a light through hole. The input/output assembly is arranged on the first housing and received in the receiving space. A side of the first housing facing the second housing is arranged with a limiting member, and the limiting member is configured to fix the input-output assembly on the first housing. The input-output assembly includes a plurality of input-output modules including a laser transmitter, a laser receiver, and at least one image collector. Each input-output module faces the light through hole.

A system includes a color camera configured to detect visible light and ultraviolet (UV) light, a UV illuminator, and a processor configured to perform operations. The operations include causing the UV illuminator to emit UV light towards a portion of an environment and receiving, from the color camera, a color image that represents the portion illuminated by the emitted UV light and by visible light incident thereon. The operations also include determining a first extent to which UV light is attenuated in connection with pixels of the color camera that have a first color and a second extent to which UV light is attenuated in connection with pixels of the color camera that have a second color. The operations further include generating a UV image based on the color image, the first extent, and the second extent, and identifying a feature of the environment by processing the UV image.

A system and method are provided for aiding an operator in operating a vehicle. In one embodiment, a system includes a sensor system configured to generate sensor data sensed from an environment of the vehicle. The system further includes a control module configured to, by a processor, generate a bowl view image of the environment based on the sensor data, identify at least one of a double object and a missing object in the bowl view image, generate a second bowl view image of the environment by re-stitching the sensor data based on the at least one of double object and missing object, and generate display data based on the second bowl view image.

Techniques for analysis and deep learning modeling of sensor-based object detection data for organic motion determination in bounded aquatic environments using underwater powered systems are described, including a light disposed substantially within a recess of a boundary wall, the light being disposed substantially underwater and configured to receive power using a conduit, and a spacer ring disposed circumferentially about an opening associated with the recess, the spacer ring being configured to secure the light within the recess and to provide a channel formed in the spacer ring, the channel being configured to receive the conduit.

A surrounding space data providing system for a control apparatus for a vehicle includes a space generation processor and a signal generation processor. The space generation processor generates a surrounding space around the vehicle with the vehicle assuming a post-control position and a post-control posture, on the basis of a motion of the vehicle based on control data to be outputted by the control apparatus. The signal generation processor generates a generated signal of a space in which an object present in the surrounding space is arranged in the surrounding space in corresponding relation to the post-control position and the post-control posture of the vehicle. The generated signal is as suppliable to the control apparatus as a detection signal to be obtained by detection by an autonomous sensor provided in the vehicle. The signal generation processor outputs the generated signal to the control apparatus in place of the detection signal.