An image processing system includes a detection processing portion, a first correction processing portion, and a reading processing portion. The detection processing portion detects an outline of an information code included in a captured image. The first correction processing portion corrects a shape of the information code based on the outline of the information code detected by the detection processing portion. The reading processing portion reads information included in the information code from the information code after correction by the first correction processing portion.

An image processing system includes a detection processing portion, a first correction processing portion, and a reading processing portion. The detection processing portion detects an outline of an information code included in a captured image. The first correction processing portion corrects a shape of the information code based on the outline of the information code detected by the detection processing portion. The reading processing portion reads information included in the information code from the information code after correction by the first correction processing portion.

Systems and methods for profiling a pallet in a warehouse can include a turntable that rotates the pallet, conveyor belts that move the pallet, and a vertical profiling structure, having cameras mounted at different locations, in a stationary position proximate to a side of the turntable. A photo booth can also be used to provide uniform lighting. A computing system can instruct a conveyor belt to automatically route the pallet onto the turntable, instruct the cameras to capture image data of the pallet as it rotates on the turntable, receive the image data, and retrieve image-based models of the pallet that were trained using images of pallets having unique identifiers. The computing system can determine, based on applying the image-based models to the image data, whether the pallet's unique identifier is identifiable, and transmit, to a warehouse management system, a notification indicating whether the unique identifier is identifiable.

A control apparatus includes at least one processor that functions as a setting a plurality of focusing points by using object information that includes information on a part of an object and is based on an image signal converted from an object image, a selection unit configured to select, from the plurality of focusing points in a search area, a main focusing point on which focusing is performed, an object determination unit configured to determine, by using a focusing state of a focusing point in a part with a highest priority in priorities set for respective parts of the object, whether or not the object included in the focusing point is the same as an object included in a previously selected main focusing point, and a decision unit configured to decide the search area based on a determination made by the object determination unit.

Methods, systems, devices, and tangible non-transitory computer readable media for determining orientation are provided. The disclosed technology can include capturing images of an environment visible in a field of view of the mobile computing device. Location data associated with a location of the mobile computing device can be received. Image data including information associated with the images can be generated. Based on the image data and one or more machine-learned models, features of one or more objects in the environment can be determined. Based on the location data and the features of the objects, respective orientations of the objects relative to the location of the mobile computing device can be determined. Furthermore, orientation data that includes a geographic orientation of the mobile computing device can be generated based on the respective (geographic) orientations of the objects.

Methods, systems, devices, and tangible non-transitory computer readable media for determining orientation are provided. The disclosed technology can include capturing images of an environment visible in a field of view of the mobile computing device. Location data associated with a location of the mobile computing device can be received. Image data including information associated with the images can be generated. Based on the image data and one or more machine-learned models, features of one or more objects in the environment can be determined. Based on the location data and the features of the objects, respective orientations of the objects relative to the location of the mobile computing device can be determined. Furthermore, orientation data that includes a geographic orientation of the mobile computing device can be generated based on the respective (geographic) orientations of the objects.

The present disclosure provides a vehicle-mounted display adjustment device and a vehicle, including an adjustment unit and a control unit. Positions of human eyes are detected and located through a detection module in the control unit, and position information of the human eyes is sent to a control module in the control unit. The control module sends a control signal to the adjustment unit according to a gaze direction of the human eyes to drive the adjustment unit to adjust an angle of the vehicle-mounted display.

Methods and systems for agricultural monitoring are disclosed. The methods and systems include: projecting, by a light source, a coherent light output on at least a part of a plant material; acquiring, by an imaging device, one or more speckle images based on the coherent light output backscattered by at least the part of the plant material; providing the one or more speckle images to a trained machine learning algorithm; identifying one or more healthy status indications of at least the part of the plant material based on one or more outputs from the trained machine learning algorithm, the one or more outputs corresponding to the one or more speckle images; and providing plant health information based on the healthy status indication. Other aspects, embodiments, and features are also claimed and described.

The present invention relates to a terahertz biometric imaging package comprising: an image sensor comprising an antenna pixel array arranged to detect terahertz radiation transmitted from an object, for capturing an image, each antenna pixel comprises a power detector including an antenna structure for receiving terahertz radiation, wherein the power detector is configured to convert a detected terahertz radiation to a sensing signal at a lower frequency than the frequency of the terahertz radiation, a package top cover arranged to cover the antenna pixel array, wherein the image sensor is configured to capture a terahertz image of an object located on an opposite side of the package top cover, a package bottom part arranged on the other side of the antenna pixel array opposite from the package top cover, wherein the antenna pixel array is encapsulated between the package top cover and the package bottom part.

Fabrication processing is executed in a chip of an image sensor. An image capturing device includes an image capturing unit (11) mounted on a vehicle and configured to generate image data by performing image capturing of a peripheral region of the vehicle, a scene recognition unit (214) configured to recognize a scene of the peripheral region based on the image data, and a drive control unit (12) configured to control drive of the image capturing unit based on the scene recognized by the scene recognition unit.