Aspects for active alignment for assembling optical imaging systems are described herein. As an example, the aspects may include aligning an optical detector with an optical component. The optical component is configured to alter a direction of one or more light beams emitted from an image displayed by an optical engine. The aspects may further include detecting, by the optical detector, a virtual image generated by the one or more light beams emitted by the optical engine; and adjusting, by a multi-axis controller, an optical path of the one or more light beams based on one or more parameters of the virtual image collected by the optical detector.

A method which may effectively provide an endoscope or other surgical instrument with a synthetic multi-camera array may comprise capturing using one or more cameras located at a distal tip of the surgical instrument, a set of images comprising first and second images. For each image in such set of images, that image may be captured by a corresponding camera from the one or more cameras, may be captured when the distal dip of the instrument is located at a corresponding point in space. Such a method may also comprise generating a three dimensional image based on compositing representations of a structure in the first and second image after applying a non-rigid transformation to one or more of those representations.

A method which may effectively provide an endoscope or other surgical instrument with a synthetic multi-camera array may comprise capturing using one or more cameras located at a distal tip of the surgical instrument, a set of images comprising first and second images. For each image in such set of images, that image may be captured by a corresponding camera from the one or more cameras, may be captured when the distal dip of the instrument is located at a corresponding point in space. Such a method may also comprise generating a three dimensional image based on compositing representations of a structure in the first and second image after applying a non-rigid transformation to one or more of those representations.

Provided is an imaging device for acquiring three-dimensional information of a workpiece surface and a two-dimensional image. An imaging device comprises a visual sensor for acquiring a two-dimensional image after acquiring three-dimensional information of a workpiece surface. A position detection device is attached to the conveyor drive motor of a conveyor that conveys a workpiece. An image processing part calculates the amount of movement of the workpiece from when the three-dimensional information is acquired to when the two-dimensional image is captured on the basis of an output of the position detection device. The image processing part moves the three-dimensional information relative to the two-dimensional image in such a manner as to correspond to the amount of movement of the workpiece in a predetermined coordinate system.

Provided is an imaging device for acquiring three-dimensional information of a workpiece surface and a two-dimensional image. An imaging device comprises a visual sensor for acquiring a two-dimensional image after acquiring three-dimensional information of a workpiece surface. A position detection device is attached to the conveyor drive motor of a conveyor that conveys a workpiece. An image processing part calculates the amount of movement of the workpiece from when the three-dimensional information is acquired to when the two-dimensional image is captured on the basis of an output of the position detection device. The image processing part moves the three-dimensional information relative to the two-dimensional image in such a manner as to correspond to the amount of movement of the workpiece in a predetermined coordinate system.

The embodiments of the disclosure provide a method for adjusting a virtual object, a host, and a computer readable storage medium. The method includes: obtaining a first field of view (FOV) of a virtual world; obtaining a second FOV of a camera, wherein a first physical object locates within the second FOV of the camera; determining a FOV ratio based on the first FOV and the second FOV; determining a first position of a first virtual object in the virtual world relative to a reference object in the virtual world, wherein the first virtual object corresponds to the first physical object; determining a second position of the first virtual object in the virtual world based on the first position and the FOV ratio; and showing the first virtual object at the second position in the virtual world.

The embodiments of the disclosure provide a method for adjusting a virtual object, a host, and a computer readable storage medium. The method includes: obtaining a first field of view (FOV) of a virtual world; obtaining a second FOV of a camera, wherein a first physical object locates within the second FOV of the camera; determining a FOV ratio based on the first FOV and the second FOV; determining a first position of a first virtual object in the virtual world relative to a reference object in the virtual world, wherein the first virtual object corresponds to the first physical object; determining a second position of the first virtual object in the virtual world based on the first position and the FOV ratio; and showing the first virtual object at the second position in the virtual world.

There are described herein methods and system for generating an inspection image of an object from radiographic imaging. The method comprises obtaining a plurality of digital images of the object positioned between a radiation source and a photon beam detector, the digital images taken at different object-detector distances or source-detector distances to create unique grain diffraction patterns in each one of the digital images, and forming the inspection image from image features common to the digital images at a common scale and removing the unique grain diffraction patterns.

There are described herein methods and system for generating an inspection image of an object from radiographic imaging. The method comprises obtaining a plurality of digital images of the object positioned between a radiation source and a photon beam detector, the digital images taken at different object-detector distances or source-detector distances to create unique grain diffraction patterns in each one of the digital images, and forming the inspection image from image features common to the digital images at a common scale and removing the unique grain diffraction patterns.

According to an aspect of the present disclosure, an interaction system for a first vehicle is provided, which comprises a processor and a memory storing processor-executable instructions that, when executed by the processor, cause the latter to implement steps comprising: receiving a first input from the first vehicle and displaying a first avatar on a display; and receiving a second input from a second vehicle and displaying a second avatar on the display, wherein the first input and the second input are updated in real time, and the first avatar and the second avatar dynamically change accordingly.