Human motion understanding and prediction is an integral aspect in our pursuit of machine intelligence and human-machine interaction systems. Current methods typically pursue a kinematics modeling approach, relying heavily upon prior anatomical knowledge and constraints. However, such an approach is hard to generalize to different skeletal model representations, and also tends to be inadequate in accounting for the dynamic range and complexity of motion, thus hindering predictive accuracy. In this work, we propose a novel approach in modeling the motion prediction problem based on stochastic differential equations and path integrals. The motion profile of each skeletal joint is formulated as a basic stochastic variable and modeled with the Langevin equation. We develop a strategy of employing GANs to simulate path integrals that amounts to optimizing over possible future paths. We conduct experiments in two large benchmark datasets, Human 3.6M and CMU MoCap. It is highlighted that our approach achieves a 12.48% accuracy improvement over current state-of-the-art methods in average.
翻译:人类运动的理解和预测是我们追求机器智能和人体-机械互动系统的一个不可分割的方面。目前的方法通常采用运动学模型方法,主要依赖先前的解剖学知识和限制。然而,这种方法很难概括不同的骨骼模型,也往往不足以计算运动的动态范围和复杂性,从而妨碍预测准确性。在这项工作中,我们提出了一个以随机差异方程式和路径构件为基础模拟运动预测问题的新办法。每个骨骼联合体的运动是作为基本的随机变量制定的,并以兰埃文方程式为模型。我们制定了一种战略,即使用GANs模拟路径构件,这等于优化未来可能的路径。我们在两个大型基准数据集,即人类3.6M和CMU MACP上进行实验。我们强调,我们的方法平均比目前的最新方法提高了12.48%的精度。