Passivity-Based Robust Shape Control of a Cable-Driven Solar Sail Boom for the CABLESSail Concept

TL;DR

This paper develops a passivity-based PD control strategy with a time-varying feedforward input to precisely and robustly control the shape of a flexible, cable-actuated solar sail boom, addressing attitude control challenges in solar sail spacecraft.

Contribution

It introduces a novel robust control approach combining passivity-based PD control with a time-varying feedforward input for the CABLESSail concept.

Findings

The control method effectively tracks time-varying boom deflections.

Simulation and prototype tests confirm robustness and precision.

The approach addresses structural flexibility and disturbance torques.

Abstract

Solar sails provide a means of propulsion using solar radiation pressure, which offers the possibility of exciting new spacecraft capabilities. However, solar sails have attitude control challenges because of the significant disturbance torques that they encounter due to imperfections in the sail and its supporting structure, as well as limited actuation capabilities. The Cable-Actuated Bio-inspired Lightweight Elastic Solar Sail (CABLESSail) concept was previously proposed to overcome these challenges by controlling the shape of the sail through cable actuation. The structural flexibility of CABLESSail introduces control challenges, which necessitate the design of a robust feedback controller for this system. The purpose of the proposed research here is to design a robust controller to ensure precise and reliable control of CABLESSail's boom. Taking into account the system dynamics and the dynamic properties of the CABLESSail concept, a passivity-based proportional-derivative (PD) controller for a single boom on the CABLESSail system is designed. To reach the nonzero desired setpoints, a feedforward input is additionally applied to the control law and a time-varying feedforward input is used instead of the constant one to effectively track a time-varying desired boom tip deflection. This control law is assessed by numerical simulations and by tests using a smaller-scale prototype of Solar Cruiser. Both the simulation and the test results show that this PD control with the time-varying feedforward input robustly controls the flexible cable-actuated solar sail.