# Precise Pointing of Cubesat Telescopes: Comparison Between Heat and   Light Induced Attitude Control Methods

**Authors:** Ravi teja Nallapu, Jekan Thangavelautham

arXiv: 1701.07562 · 2017-01-27

## TL;DR

This paper explores the use of radiometric force actuators for precise attitude control of CubeSat telescopes, offering a potentially jitter-free alternative to traditional mechanical actuators, supported by analytical and simulation studies.

## Contribution

It introduces a novel radiometric actuator design using temperature-controlled vanes in a vacuum chamber for CubeSat attitude control, demonstrating its feasibility through simulations.

## Key findings

- Radiometric actuators can produce precise torque for pointing control.
- Simulations show promising slew rates and maneuverability.
- The concept is suitable for laboratory testing and space demonstration.

## Abstract

CubeSats are emerging as low-cost tools to perform astronomy, exoplanet searches and earth observation. These satellites can target an object for science observation for weeks on end. This is typically not possible on larger missions where usage time is shared. The problem of designing an attitude control system for CubeSat telescopes is very challenging because current choice of actuators such as reaction-wheels and magnetorquers can induce jitter on the spacecraft due to moving mechanical parts and due to external disturbances. These telescopes may contain cryo-pumps and servos that introduce additional vibrations. A better solution is required. In our paper, we analyze the feasibility of utilizing solar radiation pressure (SRP) and radiometric force to achieve precise attitude control. Our studies show radiometric actuators to be a viable method to achieve precise pointing. The device uses 8 thin vanes of different temperatures placed in a near-vacuum chamber. These chambers contain trace quantities of lightweight, inert gasses like argon. The temperature gradient across the vanes causes the gas molecules to strike the vanes differently and thus inducing a force. By controlling these forces, it's possible to produce a torque to precisely point or spin a spacecraft. We present a conceptual design of a CubeSat that is equipped with these actuators. We then analyze the potential slew maneuver and slew rates possible with these actuators by simulating their performance. Our analytical and simulation results point towards a promising pathway for laboratory testing of this technology and demonstration of this technology in space.

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Source: https://tomesphere.com/paper/1701.07562