Methods and devices for presenting a virtual reality image may include rendering at least one image frame received from an application for a virtual reality image for display on a display device. The methods and devices may include receiving a selection of one of a plurality of tear thresholds that define conditions for tearing in a displayed image. The methods and devices may include determining whether the rendered frame is received prior to the selected one of the plurality of tear thresholds, wherein the selected one of the plurality of tear thresholds occurs after a frame timing event that corresponds to a deadline for initiating display of a new frame. The methods and device may include communicating the rendered image frame to the display device for presentation on the display device when the rendered frame is received prior to the selected one of the plurality of tear thresholds.

This disclosure describes techniques for synchronizing independent data streams. In some instances, a computing device couples to multiple independent sensors, such as cameras, and applies accurate timestamp information to the individual frames of sensor data from the independent sensors. After aligning these data streams by applying these accurate timestamps, the computing device may, in some instances, encode and transmit these timestamped data streams to one or more entities for further processing. In one example, a first camera (e.g., a depth camera configured to generate a depth map) may capture images of an environment, as may a second camera (e.g., an Red-Green-Blue (RGB) camera configured to generate color images). The resulting images may be temporally aligned with one another via the timestamping, and the resulting aligned images from both the depth sensor and the RGB camera may be used to create a three-dimensional (3D) model of the environment.

A vehicle imaging device for displaying an image of the outside of a vehicle on a display unit used in the vehicle includes an imaging unit that is attached to the vehicle, images of the outside of the vehicle, and outputs an imaging signal; an image signal generation unit that performs a generation process of generating an image signal indicating an image to be displayed in each line of the display unit based on the imaging signal, and outputs the image signal to the display unit; and a timing control unit that controls a timing when the image signal generation unit outputs the image signal to the display unit.

A vehicle imaging device for displaying an image of the outside of a vehicle on a display unit used in the vehicle includes an imaging unit that is attached to the vehicle, images of the outside of the vehicle, and outputs an imaging signal; an image signal generation unit that performs a generation process of generating an image signal indicating an image to be displayed in each line of the display unit based on the imaging signal, and outputs the image signal to the display unit; and a timing control unit that controls a timing when the image signal generation unit outputs the image signal to the display unit.

Focal plane distortion is prevented from standing out in the vicinity of a joint when a plurality of captured images are stitched and synthesized. A plurality of cameras are provided. Each camera includes an image sensor that outputs a signal by a raster scan scheme. Phases of a vertical synchronization signal supplied to the image sensors of the plurality of cameras are respectively shifted according to information of gap amounts of captured images of the respective cameras from a reference position in a vertical direction. Even if there are gaps in the vertical direction between the installed cameras, positional gaps between the installed image sensors due to variations in individual camera main bodies, and the like, there are no lines with largely different capture times in the vicinity of a joint of a synthesized image, and focal plane distortion is prevented from standing out in the vicinity of this joint.

Focal plane distortion is prevented from standing out in the vicinity of a joint when a plurality of captured images are stitched and synthesized. A plurality of cameras are provided. Each camera includes an image sensor that outputs a signal by a raster scan scheme. Phases of a vertical synchronization signal supplied to the image sensors of the plurality of cameras are respectively shifted according to information of gap amounts of captured images of the respective cameras from a reference position in a vertical direction. Even if there are gaps in the vertical direction between the installed cameras, positional gaps between the installed image sensors due to variations in individual camera main bodies, and the like, there are no lines with largely different capture times in the vicinity of a joint of a synthesized image, and focal plane distortion is prevented from standing out in the vicinity of this joint.

A high-speed video system is disclosed that includes a moving image absorbing disk at an image plane. The disk has a pattern that passes and blocks image data. The disk is located between an event and an image sensor, or reflects an image to the image sensor. The disk is rotated at a speed that matches the desired reconstructed image frame rate. The image sensor frame data is processed using image reconstruction techniques, such as the D-AMP or TWIST algorithm, to recover a time sequence of reconstructed images. Additional images can be reconstructed for each image sensor frame if some spatial resolution is sacrificed. For continuous video, the disk speed is adjusted to the sensor frame rate. For burst mode, a single sensor image is acquired and a short image sequence is reconstructed. This image capture system works with a variety of radiations, including infrared, light, UV and X-rays.

An image output synchronization method, performed by a programmable logic circuit connected to an oscillator, includes: configuring a count value according to a designated frame rate and a frequency of the oscillator generating a count signal by each one of a plurality of frame controllers; generating a synchronization signal periodically and outputting the synchronization signal to the frame controllers by a clock generator; and performing a synchronization procedure on a camera by each one of the frame controllers when triggered by the synchronization signal every time, with the synchronization procedure including: triggered by the count signal of the oscillator to control a frame control signal outputted to the camera according to the count value and a width of the count signal.

A synchronization signal generation function of an image transmitter is configured to generate an imaging synchronization signal. One or more processors of the image transmitter cause an imager of the image transmitter to perform new imaging every time the imaging synchronization signal is generated and cause communication data corresponding to captured image data output from the imager to be transmitted from a communicator of the image transmitter to an image receiver by radio waves. A synchronization signal generation function of the image receiver is configured to generate a display synchronization signal. One or more processors of the image receiver is configured to generate a display image corresponding to the captured image data from the communication data received by radio waves in a communicator of the image receiver and cause a monitor of the image receiver to display a newly generated display image every time the display synchronization signal is generated.

A synchronization signal generation function of an image transmitter is configured to generate an imaging synchronization signal. One or more processors of the image transmitter cause an imager of the image transmitter to perform new imaging every time the imaging synchronization signal is generated and cause communication data corresponding to captured image data output from the imager to be transmitted from a communicator of the image transmitter to an image receiver by radio waves. A synchronization signal generation function of the image receiver is configured to generate a display synchronization signal. One or more processors of the image receiver is configured to generate a display image corresponding to the captured image data from the communication data received by radio waves in a communicator of the image receiver and cause a monitor of the image receiver to display a newly generated display image every time the display synchronization signal is generated.