A method of image analysis is provided for recognition of a pattern in an image. The method includes receiving a plurality of images acquired by a camera, where the plurality of images include a plurality of optical patterns in an arrangement. The method also includes matching the arrangement to a pattern template, wherein the pattern template is a predefined arrangement of optical patterns. The method also includes identifying an optical pattern of the plurality of optical patterns as a selected optical pattern based on a position of the selected optical pattern in the arrangement. The method also includes decoding the selected optical pattern to generate an object identifier and storing the object identifier in a memory device.

A method and device are provided for positioning a mounted camera. The device includes a holding element that secures the mounted camera to the device, a wireless linkage at which remote attitude commands representing attitude changes of a remote driver are received, a local controller that interprets the remote attitude commands and generates local attitude commands that move the camera to mimic an orientation of the remote driver, and an attitude sensing element that senses a local attitude of the device. The attitude sensing element includes a gyro, an accelerometer, or a magnetometer, and jitter present in the remote attitude commands is removed and not passed on to the local attitude commands.

A method and device are provided for positioning a mounted camera. The device includes a holding element that secures the mounted camera to the device, a wireless linkage at which remote attitude commands representing attitude changes of a remote driver are received, a local controller that interprets the remote attitude commands and generates local attitude commands that move the camera to mimic an orientation of the remote driver, and an attitude sensing element that senses a local attitude of the device. The attitude sensing element includes a gyro, an accelerometer, or a magnetometer, and jitter present in the remote attitude commands is removed and not passed on to the local attitude commands.

A method of compensating for color differences between adjacent lens images in a panoramic image is disclosed. The method comprises: calculating color differences of each pair of character regions between any two adjacent lens images out of multiple lens images from a multiple-lens camera according to average color values of the character regions, each character region having a character point; determining color adjustment amounts of character points in each lens image according to the color differences of each pair of character regions; calculating a color adjustment amount of an element according to positions of the element and its two adjacent character points and the color adjustment amounts of the two adjacent character points.

An electronic device, a photographing method, and a photographing apparatus are provided. The electronic device includes a camera, a main body portion, a connecting rod, and a driving apparatus; a rear face of the camera is provided with a first arc-shaped surface that protrudes in a direction away from the camera, the main body portion is provided with a second arc-shaped surface that matches and is slidably connected to the first arc-shaped surface, and the second arc-shaped surface is provided with a through hole; the connecting rod penetrates through the through hole, and a first end of the connecting rod is hinged to the first arc-shaped surface of the camera; and the driving apparatus is connected to a second end of the connecting rod, and is used to drive the connecting rod to drive the first arc-shaped surface to slide relative to the second arc-shaped surface.

A multi-aperture imaging device is provided that includes an image sensor and an array of adjacently arranged optical channels. Each optical channel includes an optic for imaging at least one partial field of view of a total field of view onto an image sensor area of the image sensor. The device has a beam-deflector for deflecting an optical path of the optical channels and the beam-deflector includes a first beam-deflecting area operative for a first wavelength range of electromagnetic radiation passing through the optical channel; and a includes second beam-deflecting area operative for a second wavelength range of the electromagnetic radiation passing through the optical channels. The second wavelength range is different from the first wavelength range.

An improved camera system includes an uncooled thermal imaging sensor, a rotary actuator, a rotary encoder, and a slip ring. The rotary actuator is physically coupled to the uncooled thermal imaging sensor and enables the sensor to rotate a full 360 degrees any number of times relative to the system's horizontal base. Through the use of the slip ring, the sensor and the sensor's wiring can rotate freely without impedance. Notably, the sensor's wiring can be disposed through a central through-hole running the length of the rotary actuator. Therefore, prior to reaching the slip ring, the sensor and its wiring rotate in unison with the rotary actuator. The encoder is structured to monitor the angular position of the sensor in order to accurately determine where the sensor is being aimed.

An improved camera system includes an uncooled thermal imaging sensor, a rotary actuator, a rotary encoder, and a slip ring. The rotary actuator is physically coupled to the uncooled thermal imaging sensor and enables the sensor to rotate a full 360 degrees any number of times relative to the system's horizontal base. Through the use of the slip ring, the sensor and the sensor's wiring can rotate freely without impedance. Notably, the sensor's wiring can be disposed through a central through-hole running the length of the rotary actuator. Therefore, prior to reaching the slip ring, the sensor and its wiring rotate in unison with the rotary actuator. The encoder is structured to monitor the angular position of the sensor in order to accurately determine where the sensor is being aimed.

A camera assembly includes a motor configured to generate a driving power; a motor shaft that extends from the motor, such as to define a first axis, and is configured to rotate by the driving power of the motor; a pulley configured to rotate on a second axis, that is spaced from the first axis, according to rotation of the motor shaft; a belt configured to couple the motor shaft and the pulley, and convert the rotation of the motor shaft to rotation of the pulley, and tension of the belt applies a force to the motor shaft in a direction towards the second axis; a camera module configured to be mounted on the pulley and rotate together with the pulley; and an elastic body configured to apply a biasing force to the motor shaft such as to bias the motor shaft in a direction away from the second axis.