Provided for is a film conversion apparatus comprising a body and a first reel shaft having a first proximal end and a first distal end. A first reel may be disposed on the first distal end. The apparatus may include a second reel shaft having a second proximal end and a second distal end, where the first proximal end and the second proximal end are movably attached to the body. A second reel may be disposed on the second distal end. The apparatus may further include a camera configured to capture a plurality of frames and a computer configured to convert the plurality of frames to a digital format.

Motion picture film is scanned by high-resolution, continuous sprocketless scanner, producing a first sequence of digital images each representing a plurality of motion picture frames and perforations (perfs) of the film input. The first sequence of images is processed using a processor running an analysis and extraction algorithm, producing a second sequence of images each including a single, edge-stabilized frame of the motion picture.

Motion picture film is scanned by high-resolution, continuous sprocketless scanner, producing a first sequence of digital images each representing a plurality of motion picture frames and perforations (perfs) of the film input. The first sequence of images is processed using a processor running an analysis and extraction algorithm, producing a second sequence of images each including a single, edge-stabilized frame of the motion picture.

Motion picture film is scanned by high-resolution, continuous sprocketless scanner, producing a first sequence of digital images each representing a plurality of motion picture frames and perforations (perfs) of the film input. The first sequence of images is processed using a processor running an analysis and extraction algorithm, producing a second sequence of images each including a single, edge-stabilized frame of the motion picture.

Disclosed is an electronic device including a memory that stores at least one command associated with an image encoding and a processor electrically connected to the memory. The command executed while the processor is operated divides a content generation buffer allocated in association with a specified content generation into a plurality of partial areas, stitches a previous image and a present image with respect to at least a portion of an area in which the present image overlaps with the previous image, and performs a parallel encoding on each of the partial areas of the stitched images in a specified block size when the stitched images are stored in the content generation buffer.

Provided are methods and systems for automated location and identification of multiple objects in an aircraft cabin. A method utilizes a wireless client, RFID reader, and camera, which together form a set. Each set is associated with a specific inspection zone in the cabin. The RFID reader determines the presence of a RFID tag in only one zone. Further, the camera captures an image of that zone. A data feedback is generated based on both the image and the RFID reader response. The data feedback is transmitted by the wireless client to a router and is analyzed to determine the presence of the object in the inspection zone and, if present, the identity of the object. The data feedback is associated with the location of the zone in the aircraft cabin, which is known or may be determined using a set of wireless routers positioned throughout the cabin.

Motion picture film is scanned by high-resolution, continuous sprocketless scanner, producing a first sequence of digital images each representing a plurality of motion picture frames and perforations (perfs) of the film input. The first sequence of images is processed using a processor running an analysis and extraction algorithm, producing a second sequence of images each including a single, edge-stabilized frame of the motion picture.

Motion picture film is scanned by high-resolution, continuous sprocketless scanner, producing a first sequence of digital images each representing a plurality of motion picture frames and perforations (perfs) of the film input. The first sequence of images is processed using a processor running an analysis and extraction algorithm, producing a second sequence of images each including a single, edge-stabilized frame of the motion picture.

The present invention provides a motion picture film image stabilization method that uses (a) a coincident exposure process to capture a predetermined number of marked frames of a film wherein each marked frame includes a marked image and fiducial mark(s); (b) developing the film; (c) digitizing the film to convert each of the marked frames into a digital marked scan having a digital image of the marked image and the digital fiducial mark(s); and repositioning each digital image of each digital marked scan using dimensional position of the digital fiducial marks. This method can be achieved via the present invention's system comprising a motion picture film camera, a fiducial system, a scanner, and a processor.

The present invention provides a motion picture film image stabilization method that uses (a) a coincident exposure process to capture a predetermined number of marked frames of a film wherein each marked frame includes a marked image and fiducial mark(s); (b) developing the film; (c) digitizing the film to convert each of the marked frames into a digital marked scan having a digital image of the marked image and the digital fiducial mark(s); and repositioning each digital image of each digital marked scan using dimensional position of the digital fiducial marks. This method can be achieved via the present invention's system comprising a motion picture film camera, a fiducial system, a scanner, and a processor.