Groupwise registration of aerial images
This work addresses the problem of accurately registering aerial images over time for applications like image understanding, though it is incremental in improving existing methods.
The paper tackles time-separated aerial image registration by introducing a set-based paradigm that uses a constraints graph with local pair-wise constraints and a holistic representation, achieving greater accuracy, reliability, and reduced computational cost compared to state-of-the-art methods, with average registration error decreasing as more images are added.
This paper addresses the task of time separated aerial image registration. The ability to solve this problem accurately and reliably is important for a variety of subsequent image understanding applications. The principal challenge lies in the extent and nature of transient appearance variation that a land area can undergo, such as that caused by the change in illumination conditions, seasonal variations, or the occlusion by non-persistent objects (people, cars). Our work introduces several novelties: (i) unlike all previous work on aerial image registration, we approach the problem using a set-based paradigm; (ii) we show how local, pair-wise constraints can be used to enforce a globally good registration using a constraints graph structure; (iii) we show how a simple holistic representation derived from raw aerial images can be used as a basic building block of the constraints graph in a manner which achieves both high registration accuracy and speed. We demonstrate: (i) that the proposed method outperforms the state-of-the-art for pair-wise registration already, achieving greater accuracy and reliability, while at the same time reducing the computational cost of the task; and (ii) that the increase in the number of available images in a set consistently reduces the average registration error.