Legged Robot State-Estimation Through Combined Forward Kinematic and Preintegrated Contact Factors

TL;DR

This paper introduces a novel state-estimation method for legged robots that combines forward kinematic and contact factors within a factor graph framework, improving localization especially when visual data is unreliable.

Contribution

It presents the integration of forward kinematic and preintegrated contact factors into a real-time factor graph for enhanced legged robot localization.

Findings

Reduces drift in robot localization.

Improves accuracy when visual tracking is lost.

Validated with simulated and real data from Cassie robot.

Abstract

State-of-the-art robotic perception systems have achieved sufficiently good performance using Inertial Measurement Units (IMUs), cameras, and nonlinear optimization techniques, that they are now being deployed as technologies. However, many of these methods rely significantly on vision and often fail when visual tracking is lost due to lighting or scarcity of features. This paper presents a state-estimation technique for legged robots that takes into account the robot's kinematic model as well as its contact with the environment. We introduce forward kinematic factors and preintegrated contact factors into a factor graph framework that can be incrementally solved in real-time. The forward kinematic factor relates the robot's base pose to a contact frame through noisy encoder measurements. The preintegrated contact factor provides odometry measurements of this contact frame while accounting for possible foot slippage. Together, the two developed factors constrain the graph optimization problem allowing the robot's trajectory to be estimated. The paper evaluates the method using simulated and real sensory IMU and kinematic data from experiments with a Cassie-series robot designed by Agility Robotics. These preliminary experiments show that using the proposed method in addition to IMU decreases drift and improves localization accuracy, suggesting that its use can enable successful recovery from a loss of visual tracking.