Action Units That Constitute Trainable Micro-expressions (and A Large-scale Synthetic Dataset)

Due to the expensive data collection process, microexpression datasets are generally much smaller in scale than those in other computer vision fields, rendering largescale training less stable and feasible. In this paper, we aim to develop a protocol to automatically synthesize microexpression training data that 1) are on a large scale and 2) allow us to train recognition models with strong accuracy on real-world test sets. Specifically, we discover three types of Action Units (AUs) that can well constitute trainable micro-expressions. These AUs come from real-world micro-expressions, early frames of macro-expressions, and the relationship between AUs and expression labels defined by human knowledge. With these AUs, our protocol then employs large numbers of face images with various identities and an existing face generation method for microexpression synthesis. Micro-expression recognition models are trained on the generated micro-expression datasets and evaluated on real-world test sets, where very competitive and stable performance is obtained. The experimental results not only validate the effectiveness of these AUs and our dataset synthesis protocol but also reveal some critical properties of micro-expressions: they generalize across faces, are close to early-stage macro-expressions, and can be manually defined.

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