Provided are a panoramic photographing method and device, a camera and a mobile terminal, the method includes: when panoramic photographing is performed, firstly, a ranging device acquires the depth information of the object to be photographed, that is the distance between the object to be photographed and the photographing device, and then the offset corresponding to the current distance is acquired according to a preset mapping relationship, and the original imaging of the object to be photographed is subsequently shifted in the panoramic image to form a corrected panoramic image.

An image processing method of processing image data generated by an image sensor, the image sensor including a pixel array, includes calculating position information according to pixel positions in the image data, the pixel positions corresponding to pixels of the pixel array, and correcting a phase difference of the image data based on the position information.

An image processing method of processing image data generated by an image sensor, the image sensor including a pixel array, includes calculating position information according to pixel positions in the image data, the pixel positions corresponding to pixels of the pixel array, and correcting a phase difference of the image data based on the position information.

A three-dimensional (3D) sensing apparatus together with a projector subassembly is provided. The 3D sensing apparatus includes two cameras, which may be configured to capture ultraviolet and/or near-infrared light. The 3D sensing apparatus may also contain an optical filter and one or more computing processors that signal a simultaneous capture using the two cameras and processing the captured images into depth. The projector subassembly of the 3D sensing apparatus includes a laser diode, one or optical elements, and a photodiode that are useable to enable 3D capture.

A three-dimensional (3D) sensing apparatus together with a projector subassembly is provided. The 3D sensing apparatus includes two cameras, which may be configured to capture ultraviolet and/or near-infrared light. The 3D sensing apparatus may also contain an optical filter and one or more computing processors that signal a simultaneous capture using the two cameras and processing the captured images into depth. The projector subassembly of the 3D sensing apparatus includes a laser diode, one or optical elements, and a photodiode that are useable to enable 3D capture.

Systems and methods are provided for generating a rear view image display for a motor vehicle. A rear view system includes an optical sensor disposed at the motor vehicle and configured to capture image data, a computational unit coupled to the optical sensor by a cable connection and configured to execute program instructions stored on a computer-readable medium to modify the image data for presentation, and a display device coupled to the computational unit and configured to receive the modified image data from the computational unit and display the modified image data to a driver of the motor vehicle. The computational unit is further configured to receive software calibration to optimize modification of the image data.

Systems and methods are provided for generating a rear view image display for a motor vehicle. A rear view system includes an optical sensor disposed at the motor vehicle and configured to capture image data, a computational unit coupled to the optical sensor by a cable connection and configured to execute program instructions stored on a computer-readable medium to modify the image data for presentation, and a display device coupled to the computational unit and configured to receive the modified image data from the computational unit and display the modified image data to a driver of the motor vehicle. The computational unit is further configured to receive software calibration to optimize modification of the image data.

Systems and methods facilitate digital zoom of live video based on remote user instructions. A user of a remote device may desire to zoom in on a particular aspect of a copy of a full image captured by a sensor at a first resolution and communicated to the remote device at a second resolution less than the first resolution. A selection that corresponds to a user-selected area of the copy and corresponding to a portion of the sensor is received by the sensor. Based on the selection, an instruction is generated to capture a second electronic image utilizing the portion of the sensor with the first resolution. Thus, rather than zooming into the first electronic image at the second resolution, the second electronic image corresponding to the portion of the sensor is captured at the first resolution and then converted to the second resolution, resulting in a higher resolution zoom.

Systems and methods facilitate digital zoom of live video based on remote user instructions. A user of a remote device may desire to zoom in on a particular aspect of a copy of a full image captured by a sensor at a first resolution and communicated to the remote device at a second resolution less than the first resolution. A selection that corresponds to a user-selected area of the copy and corresponding to a portion of the sensor is received by the sensor. Based on the selection, an instruction is generated to capture a second electronic image utilizing the portion of the sensor with the first resolution. Thus, rather than zooming into the first electronic image at the second resolution, the second electronic image corresponding to the portion of the sensor is captured at the first resolution and then converted to the second resolution, resulting in a higher resolution zoom.

Example embodiments relate to identifying defects in optical detector systems based on extent of stray light. An example embodiment includes a method. The method includes capturing, using an optical detector system, an image of a scene that includes a bright object. The method also includes determining a location of the bright object within the image. Further, the method includes determining, based on the location of the bright object within the image, an extent of stray light from the bright object that is represented in the image. In addition, the method includes determining, by comparing the extent of stray light from the bright object that is represented in the image to a predetermined threshold extent of stray light, whether one or more defects are present within the optical detector system. The predetermined threshold extent of stray light corresponds to an expected extent of stray light.