A depth calculation processor comprises: an input port, configured to receive image data from an image sensor; a demultiplexer, connected to the input port, and configured to demultiplex the image data from the input port and output first image data into a first line and second image data into a second line; a grayscale image engine, configured to process the first image data from the first line to generate processed first image data; a depth image engine, configured to receive the second image data from the second line, and calculate depth image data based on the second image data; a multiplexer, configured to output the processed first image data from the grayscale image engine and the depth image data from the depth image engine; and an output port, configured to output the processed first image data and the depth image data from the multiplexer.

The invention relates to a system (1) for identifying a device using a camera and for remotely controlling the identified device. The system is configured to obtain an image (21) captured with a camera. The image captures at least a surrounding of a remote controllable device (51). The system is further configured to analyze the image to recognize one or more objects (57) and/or features in the surrounding of the remote controllable device and select an identifier associated with at least one of the one or more objects and/or features from a plurality of identifiers stored in a memory. The memory comprises associations between the plurality of identifiers and remote controllable devices and the selected identifier is associated with the remote controllable device. The system is further configured to determine a control mechanism for controlling the remote controllable device and control the remote controllable device using the determined control mechanism.

A dual-camera device includes a first camera and a second camera, where the first camera includes a first motor, and the first motor includes at least one first Hall effect sensor, where the second camera includes a second motor, the second motor and the first motor are disposed in parallel, the second motor includes N second coils and N second magnets, the second coils are configured to levitate and support the second magnets during power-on, N is a positive integer and is a multiple of four. A distance between a first disposition location of the first Hall effect sensor and a second disposition location of the second magnets in the second motor is greater than or equal to a first preset distance.

A terminal device and a shooting method are provided. The terminal device includes a main body, a driving component, a camera component, and a connection element. The driving component is mounted on the main body. The camera component is connected to the connection element. The connection element is rotatably mounted on the driving component. The driving component is configured to place the camera component at a first position or a second position by driving the connection element and the camera component can perform compound motion relative to the main body. The compound motion includes linear and rotational sub-motion. In the disclosure, the driving component drives the camera component to perform rotational motion, so as to change a shooting angle of the camera component.

This invention provides a system and method for utilizing a wireless, handheld communication device to image a scene in multiple directions, so as to include multiple parties in addition to the user, and also, optionally, to project images on a plurality of display screens—for example a user-facing screen on the front face of the phone and an opposing screen on the rear/back face of the phone that faces (e.g.) a chat participant other than the user (an audience). The housing of the smartphone is adapted to provide a multi-camera and multi-screen arrangement. More particularly, the housing of the smartphone is adapted to include (at least) a front-directed camera and a rear-directed camera on respective front and rear faces, and openings along the left and right side edges for small-scale cameras and associated protective windows that are directed to image the left and right areas adjacent to the phone.

Aspects of the present disclosure involve a system comprising a computer-readable storage medium storing at least one program, method, and user interfaces to facilitate electronic chat conversations between users via multiple modes of electronic communication. A conversation view is displayed on a touch screen display of a client device. The conversation view presents messages exchanged between a first user and at least one other user in an electronic chat conversation. A user input comprising a touch gesture corresponding to an interaction with the display of the conversation view is received. Based on the user input, a camera feed view is displayed on the touch screen display. The camera feed view comprises a display of image data and enables a user to create a message comprising one or more images. A message is generated, and an indication of the message is displayed in the conversation view.

A system, method, and computer-readable medium are disclosed for creating image recognition models, which can be operated on smartphone or similar device. The smartphone captures images of hardware in a data center. The captured images are processed to produce a full set of annotated images. The full set is minimized to a simplified set and trained to create a mobile image recognition model implemented by the smartphone or similar device.

Systems and methods for controlling Internet of Things (IoT) devices using an augmented reality (AR) camera are provided. The system includes a sensor and a server that receives an input from the sensor and presents an AR object on the display of the AR camera device that corresponds to the input from the sensor. A response to the displayed AR object from a user of the AR camera device is used to select a command to send to one or more IoT devices to perform an action corresponding to the user response to the displayed AR object. In an example, an AR smoke object is overlayed on the AR camera display in response to a smoke detection signal from a smoke detector. In response to the user swiping or gesturing to push away the AR smoke object, a window opening command is sent to one or more IoT enabled windows.

A lens module includes a carrier having an internal space, a lens unit including lens groups and installed in the carrier so that at least two of the lens groups are independently movable in a length direction of the carrier, a guide unit including guide members arranged on both side surfaces of the lens groups to guide movement of the movable lens groups, and driving wires connected to each of the guide members and formed of a shape memory alloy, wherein each of the movable lens groups is connected to a pair of guide members disposed on both sides of the carrier.

A method for setting parameter settings of an image signal processor (ISP) of a camera of a mobile device based on a user selection may include controlling a display of the mobile device to display a plurality of images, each of which is associated with corresponding parameter settings. The method may include receiving, via a user interface (UI) of the mobile device, the user selection in relation to an image of the plurality of images. The method may include determining selected parameter settings based on the user selection in relation to the image. The method may include setting the parameter settings of the ISP, based on the selected parameter settings, to permit the ISP to process a raw image from an image sensor of the mobile device using the selected parameter settings.