Event cameras are bio-inspired sensors that perform well in challenging illumination conditions and have high temporal resolution. However, their concept is fundamentally different from traditional frame-based cameras. The pixels of an event camera operate independently and asynchronously. They measure changes of the logarithmic brightness and return them in the highly discretised form of time-stamped events indicating a relative change of a certain quantity since the last event. New models and algorithms are needed to process this kind of measurements. The present work looks at several motion estimation problems with event cameras. The flow of the events is modelled by a general homographic warping in a space-time volume, and the objective is formulated as a maximisation of contrast within the image of warped events. Our core contribution consists of deriving globally optimal solutions to these generally non-convex problems, which removes the dependency on a good initial guess plaguing existing methods. Our methods rely on branch-and-bound optimisation and employ novel and efficient, recursive upper and lower bounds derived for six different contrast estimation functions. The practical validity of our approach is demonstrated by a successful application to three different event camera motion estimation problems.
翻译:事件相机是生物感应器,在具有挑战性的照明条件下效果良好,具有高时间分辨率。然而,它们的概念与传统的框架照相机有根本的不同。事件相机的像素独立和无同步地运行。它们测量对数亮度的变化,并以高度分散的时间标记事件的形式返回它们,表明自上次事件以来某种数量的变化。处理这类测量需要新的模型和算法。目前的工作审视了事件相机的一些运动估计问题。事件的流动以一个空间时段一般的全景图谱转换为模型,目标是在扭曲事件图像范围内实现最大程度的对比。我们的核心贡献包括为这些一般非孔径的问题制定全球最佳解决办法,从而消除了对初步假设中某种特定数量的相对变化的依赖。我们的方法依赖于分支和边缘的优化,并采用新颖和高效的、循环式的上下层和下层,用于六个不同的对比估测功能。我们的方法的实际有效性表现在成功应用三个不同事件模型的模型上。