Abstract
Dynamic Vision Sensors differ from conventional cameras in that only intensity changes of individual pixels are perceived and transmitted as an asynchronous stream instead of an entire frame. The technology promises, among other things, high temporal resolution and low latencies and data rates. While such sensors currently enjoy much scientific attention, there are only little publications on practical applications. One field of application that has hardly been considered so far, yet potentially fits well with the sensor principle due to its special properties, is automatic visual inspection. In this paper, we evaluate current state-of-the-art processing algorithms in this new application domain. We further propose an algorithmic approach for the identification of ideal time windows within an event stream for object classification. For the evaluation of our method, we acquire two novel datasets that contain typical visual inspection scenarios, i.e., the inspection of objects on a conveyor belt and during free fall. The success of our algorithmic extension for data processing is demonstrated on the basis of these new datasets by showing that classification accuracy of current algorithms is highly increased. By making our new datasets publicly available, we intend to stimulate further research on application of Dynamic Vision Sensors in machine vision applications.
Highlights
In recent years, a new type of image sensor principle has undergone a rapid development
The performance of the presented data processing methods and the impact of the proposed Contrast-Based Windowing (CBW) approach are comparatively evaluated on the basis of the two datasets from Section 4
We presented a modular pipeline including the common processing steps in machine vision for the new Dynamic Vision Sensors (DVS) principle
Summary
A new type of image sensor principle has undergone a rapid development. -called Dynamic Vision Sensors (DVS) merely perceive changes in intensity and encode this information as events in an asynchronous stream. Theoretical advantages of the sensor principle have been discussed thoroughly [1], their fields of application still remain somewhat unclear. It has recently been shown that the strength of the concept is evident in sparsely populated scenes [2]. This does match very well to the fields of application considered so far
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