A method of processing an image using an electronic device is provided. The method includes displaying at least part of a first image which is obtained through a first image sensor and at least part of a second image which is obtained through a second image sensor through a display unit which is functionally connected to the electronic device, storing the at least part of the first image, storing the at least part of the second image in response to a detecting of a signal, and storing the at least part of the first image and the at least part of the second image to be simultaneously replayed as at least one image.

In an image processing apparatus that performs interval moving image capturing, interval image capturing and lighten compositing are sequentially performed, whereby an effective interval moving image can be obtained without advance techniques and cumbersome procedure that have been required for providing special effects to moving images.

Systems, apparatuses, and/or methods may define a priority of image memory traffic based on image sensor protocol metadata. For example, a metadata identifier may identify image sensor protocol metadata corresponding to an image sensor physical layer and/or an image sensor link layer. Moreover, a prioritizer may define a priority of the image memory traffic based on the image sensor protocol metadata. The priority may be used to control client access to dedicated memory and/or to shared memory.

An image capture device continuously generates time-lapse video frames to be included within a time-lapse video using a dynamic time-lapse video frame rate, with the value of the dynamic time-lapse video frame rate changing based on activation of a trigger to change the dynamic time-lapse video frame rate. The dynamic time-lapse video frame rate alternates between different values.

Systems, apparatuses, and/or methods may define a priority of image memory traffic based on image sensor protocol metadata. For example, a metadata identifier may identify image sensor protocol metadata corresponding to an image sensor physical layer and/or an image sensor link layer. Moreover, a prioritizer may define a priority of the image memory traffic based on the image sensor protocol metadata. The priority may be used to control client access to dedicated memory and/or to shared memory.

A method for monitoring an additive manufacturing process during fabrication of a component part is disclosed. In various embodiments, the method includes the steps of selecting a sensing matrix; orienting a sensor toward a surface of the component part; generating a discrete time signal, based on data obtained from the sensor, the discrete time signal being representative of a process condition of the component part while the component part is undergoing the additive manufacturing process; compressing the discrete time signal using the sensing matrix to form a compressed measurement signal; and storing the compressed measurement signal in a storage device while the component part is undergoing the additive manufacturing process. In various embodiments, selecting the sensing matrix comprises selecting a basis function. In various embodiments, the basis function is determined using a random time sampling.

A system and method for capturing and customizing relevant image and allowing a user to share the relevant image over the network. The method captures an image containing features of a subject. The method then establishes a wireless connection with an external hardware unit. The method transmits the captured image to the external hardware unit. Further, the method comprises a step of identifying the features in the received image. The method determines states of a light sensor and an IR sensor. Furthermore, the method comprises aligns a camera module of the external hardware unit with the identified features of the received image to capture a relevant image. The light sensor and IR sensor are integrated with the camera module. The method then stores the relevant image in a storage module configured with the external hardware unit. Then the method customizes the relevant image based on the identified features.

A pixel clock generating device includes a high-frequency clock generator, a comparer, a pixel clock generator, and a value switcher. The high-frequency clock generator is configured to generate a high-frequency clock. The comparer is configured to measure a time interval between a leading-end synchronizing signal and a trailing-end synchronizing signal in a main scanning and calculate an error between the time interval and a target value. The pixel clock generator is configured to generate a pixel clock based on the high-frequency clock and a pixel clock frequency and correct the pixel clock based on the error. The value switcher, including a plurality of groups of values with which the pixel clock is generated, is configured to switch between the plurality of groups of values according to a switching signal after the trailing-end synchronizing signal is inputted, the comparer calculates the error, and the pixel clock generator corrects the pixel clock.

In an image processing apparatus that performs interval moving image capturing, interval image capturing and lighten compositing are sequentially performed, whereby an effective interval moving image can be obtained without advance techniques and cumbersome procedure that have been required for providing special effects to moving images.

Embodiments of the disclosure provide a method, an apparatus, and a readable storage medium for controlling a time-lapse photographing. The method includes detecting whether a time-lapse photographing session has ended; determining a time of a next turning-on of the camera in response to the detection that the session has not ended, the time of the next turning-on of the camera being earlier than a time of a next photographing event, the time of the next photographing event being a sum of a time of a current photographing event and a time interval between photographing events; configuring a real time clock based on the time of the next turning-on of the camera; shutting down the camera; starting up the camera when the time of the next turning-on of the camera is reached; and taking a photograph when the time of the next photographing event is reached.