Reconstructing Human Pose From Inertial Measurements: A Generative Model-Based Compressive Sensing Approach

Nguyen Quang Hieu;Dinh Thai Hoang;Diep N. Nguyen;Mohammad Abu Alsheikh
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Abstract

The ability to sense, localize, and estimate the 3D position and orientation of the human body is critical in virtual reality (VR) and extended reality (XR) applications. This becomes more important and challenging with the deployment of VR/XR applications over the next generation of wireless systems such as 5G and beyond. In this paper, we propose a novel framework that can reconstruct the 3D human body pose of the user given sparse measurements from Inertial Measurement Unit (IMU) sensors over a noisy wireless environment. Specifically, our framework enables reliable transmission of compressed IMU signals through noisy wireless channels and effective recovery of such signals at the receiver, e.g., an edge server. This task is very challenging due to the constraints of transmit power, recovery accuracy, and recovery latency. To address these challenges, we first develop a deep generative model at the receiver to recover the data from linear measurements of IMU signals. The linear measurements of the IMU signals are obtained by a linear projection with a measurement matrix based on the compressive sensing theory. The key to the success of our framework lies in the novel design of the measurement matrix at the transmitter, which can not only satisfy power constraints for the IMU devices but also obtain a highly accurate recovery for the IMU signals at the receiver. This can be achieved by extending the set-restricted eigenvalue condition of the measurement matrix and combining it with an upper bound for the power transmission constraint. Our framework can achieve robust performance for recovering 3D human poses from noisy compressed IMU signals. Additionally, our pre-trained deep generative model achieves signal reconstruction accuracy comparable to an optimization-based approach, i.e., Lasso, but is an order of magnitude faster.
从惯性测量重建人体姿态:基于生成模型的压缩传感方法
在虚拟现实(VR)和扩展现实(XR)应用中,感知、定位和估计人体三维位置和方向的能力至关重要。随着 VR/XR 应用在下一代无线系统(如 5G 及其他)上的部署,这种能力变得更加重要和具有挑战性。在本文中,我们提出了一个新颖的框架,该框架可以在嘈杂的无线环境中,根据来自惯性测量单元(IMU)传感器的稀疏测量值重建用户的三维人体姿态。具体来说,我们的框架能够通过嘈杂的无线信道可靠地传输压缩的 IMU 信号,并在接收器(如边缘服务器)上有效地恢复这些信号。由于发射功率、恢复精度和恢复延迟的限制,这项任务非常具有挑战性。为了应对这些挑战,我们首先在接收器上开发了一个深度生成模型,以便从 IMU 信号的线性测量中恢复数据。IMU 信号的线性测量是通过基于压缩传感理论的测量矩阵线性投影获得的。我们的框架成功的关键在于发射器测量矩阵的新颖设计,它不仅能满足 IMU 设备的功率约束,还能在接收器处获得高精度的 IMU 信号恢复。这可以通过扩展测量矩阵的集合限制特征值条件并将其与功率传输约束的上限相结合来实现。我们的框架可以从有噪声的压缩 IMU 信号中恢复三维人体姿态,从而实现稳健的性能。此外,我们的预训练深度生成模型实现了与基于优化的方法(即 Lasso)相当的信号重建精度,但速度却快了一个数量级。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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