Deghosting mosaics using multiperspective plane sweep

Abstract

A system and method for deghosting mosaics provides a novel multiperspective plane sweep approach for generating an image mosaic from a sequence of still images, video images, scanned photographic images, computer generated images, etc. This multiperspective plane sweep approach uses virtual camera positions to compute depth maps for columns of overlapping pixels in adjacent images. Object distortions and ghosting caused by image parallax when generating the image mosaics are then minimized by blending pixel colors, or grey values, for each computed depth to create a common composite area for each of the overlapping images. Further, the multiperspective plane sweep approach described herein is both computationally efficient, and applicable to both the case of limited overlap between the images used for creating the image mosaics, and to the case of extensive or increased image overlap.

Description

CROSS REFERENCE TO RELATED APPLICATIONS [0001] This application is a Continuation Application of U.S. patent application Ser. No. 10 / 172,859, filed on Jun. 15, 2002 by Kang, et al., and entitled “A SYSTEM AND METHOD DEGHOSTING MOSAICS USING MULTIPERSPECTIVE PLANE SWEEP”.BACKGROUND [0002] 1. Technical Field [0003] The invention is related to a system for mosaicing images, and in particular, to a system and method for minimizing object distortions and ghosting caused by image parallax. [0004] 2. Related Art [0005] In general, image mosaics are a combination of two or more overlapping images that serve to present an overall view of a scene from perspectives other than those of the individual images used to generate the mosaic. In other words, image-based rendering techniques such as the creation of image mosaics are used to render photorealistic novel views from collections of real or pre-rendered images which allow a user or viewer to look in any desired direction. Such novel views ar...

AI Technical Summary

Benefits of technology

[0013] Object distortions and ghosting caused by image parallax when generating the image mosaics is then minimized by blending pixel colors, or grey values, for each computed depth to create a common composite area for each of the overlapping images. Further, the multiperspective plane sweep approach described herein is both computationally efficient, and applicable to the case of limited overlap between the images used for creating the image mosaics. Note the multiperspective plane sweep approach described herein also works well in cases of increased image overlap.

[0017] Once the images have been warped, any of a number of conventional alignment techniques is used to identify overlapping regions between two or more images which are to be composited. Non-overlapping regions are then associated with their respective original camera locations (or rendering origins), while each column of pixels in overlapping areas of the images are associated with virtual camera locations existing between the two original camera locations. The use of such virtual camera locations serves to minimize object distortion, which is unavoidable, while producing a practically seamless composite image. Computing the appearance of each column within the overlapping region is accomplished using a modification of a conventional plane sweep technique. This modification is termed “multi-perspective plane sweep” (MPPS), because the plane sweep for every column in the overlapping region is computed using a different virtual camera position.

Problems solved by technology

Unfortunately, using large sets of overlapping images having a high degree of overlap for generating mosaics is typically computationally expensive.

Further, where the set of overlapping images available for generating a mosaic comprises a sparse or limited set of images taken at slightly displaced locations, the problem of ghosting due to the presence of parallax becomes a major concern.

Specifically, any deviations from a pure parallax-free motion model or an ideal pinhole camera model can result in local misregistrations between the combined images.

Unfortunately, while useful, because the aforementioned patch-based deghosting technique is purely image-based, it is only capable of addressing small amounts of motion parallax.

Consequently, this scheme can not fully address significant parallax problems.

Further, the corrective warping used in this patch-based deghosting technique often produces unrealistic-looking results.

In addition, the patch-based deghosting technique summarized above tends to is be computationally expensive.

Unfortunately, this scheme can not provide a satisfactory solution in the case of sparse sampling, such as where overlap between images is 50% or less and where parallax is a significant concern.

In addition, because of the dense sampling, the aforementioned scheme tends to be computationally expensive.

Images