Riemannian geometric approach to optimal binocular rotation, pyramid based interpolation and bio-mimetic pan-tilt movement

Bijoy K. Ghosh, Bhagya Athukorallage
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Abstract

Over the past several years, we have been studying the problem of optimally rotating a rigid sphere about its center, where the rotation is actuated by a triplet of external torques acting on the body. The control objective is to repeatedly direct a suitable radial vector, called the gaze vector, towards a stationary point target in IR3. The orientation of the sphere is constrained to lie in a suitable submanifold of SO(3). Historically, the constrained rotational movements were studied by physiologists in the nineteenth century, interested in eye and head movements. In this paper we revisit the gaze control problem, where two visual sensors, are tasked to simultaneously stare at a point target in the visual space. The target position changes discretely and the problem we consider is how to reorient the gaze directions of the sensors, along the optimal pathway of the human eyes, to the new location of the target. This is done by first solving an optimal control problem on the human binocular system. Next, we use these optimal control and show that a pan-tilt system can be controlled to follow the gaze trajectory of the human eye requiring a nonlinear static feedback of the pan and tilt angles and their derivatives. Our problem formulation uses a new Riemannian geometric description of the orientation space. The paper also introduces a new, pyramid based interpolation method, to implement the optimal controller.

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最优双目旋转、基于金字塔的插值和仿生平移的黎曼几何方法
在过去几年中,我们一直在研究一个刚性球体围绕其中心进行最佳旋转的问题,旋转是由作用在球体上的三重外部力矩驱动的。控制目标是将一个合适的径向矢量(称为凝视矢量)反复指向 IR3 中的一个静止点目标。球体的方向受限于 SO(3) 的一个合适的子曲面。十九世纪的生理学家曾对受限旋转运动进行过研究,他们对眼球和头部运动很感兴趣。在本文中,我们将重新讨论凝视控制问题,即两个视觉传感器同时盯着视觉空间中的一个点目标。目标位置会发生离散变化,我们要考虑的问题是如何沿着人眼的最佳路径,将传感器的注视方向调整到目标的新位置。为此,我们首先要解决人类双眼系统的最优控制问题。接下来,我们利用这些最优控制,证明可以控制云台系统,使其遵循人眼的注视轨迹,而这需要云台和俯仰角度及其导数的非线性静态反馈。我们的问题表述使用了新的方位空间黎曼几何描述。本文还介绍了一种新的基于金字塔的插值方法,以实现最优控制器。
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