Orbital Environment Simulator

Pointing Control for Low Altitude Triple Cubesat Space Darts

Pointing Control for Low Altitude Triple Cubesat Space Darts August 12 th, 2009 U.S. Naval Research Laboratory Washington, D.C. Code 8231-Attitude Control System James Armstrong, Craig Casey, Glenn Creamer,

PASSIVE ATTITUDE STABILIZATION FOR SMALL SATELLITES

University of Kentucky UKnowledge University of Kentucky Master's Theses Graduate School 2010 PASSIVE ATTITUDE STABILIZATION FOR SMALL SATELLITES Samir Ahmed Rawashdeh University of Kentucky, SAMIR.RAWASHDEH@GMAIL.COM

AERODYNAMIC ATTITUDE STABILIZATION FOR A RAM-FACING CUBESAT

AAS 09-084 AERODYNAMIC ATTITUDE STABILIZATION FOR A RAM-FACING CUBESAT Samir Rawashdeh, * David Jones, Daniel Erb, * Anthony Karam, and James E. Lumpp, Jr. This paper describes the design, modeling, and

Passive Magnetic Attitude Control for CubeSat Spacecraft

Passive Magnetic Attitude Control for CubeSat Spacecraft David Gerhardt Advisor: Dr. Scott Palo University of Colorado at Boulder Department of Aerospace Engineering Sciences August 11, 2010 Motivation

Satellite Attitude Control System Design Using Reaction Wheels Bhanu Gouda Brian Fast Dan Simon

Satellite Attitude Control System Design Using Reaction Wheels Bhanu Gouda Brian Fast Dan Simon Outline 1. Overview of Attitude Determination and Control system. Problem formulation 3. Control schemes

AS3010: Introduction to Space Technology

AS3010: Introduction to Space Technology L E C T U R E 22 Part B, Lecture 22 19 April, 2017 C O N T E N T S Attitude stabilization passive and active. Actuators for three axis or active stabilization.

Design and Implementation of a Space Environment Simulation Toolbox for Small Satellites

56th International Astronautical Congress 25 35th Student Conference (IAF W.) IAC-5-E2.3.6 Design and Implementation of a Space Environment Simulation Toolbox for Small Satellites Rouzbeh Amini, Jesper

Lecture Module 5: Introduction to Attitude Stabilization and Control

1 Lecture Module 5: Introduction to Attitude Stabilization and Control Lectures 1-3 Stability is referred to as a system s behaviour to external/internal disturbances (small) in/from equilibrium states.

EE363 Automatic Control: Midterm Exam (4 problems, 90 minutes)

EE363 Automatic Control: Midterm Exam (4 problems, 90 minutes) ) Block diagram simplification (0 points). Simplify the following block diagram.,i.e., find the transfer function from u to y. Your answer

Design Architecture of Attitude Determination and Control System of ICUBE

Design Architecture of Attitude Determination and Control System of ICUBE 9th Annual Spring CubeSat Developers' Workshop, USA Author : Co-Author: Affiliation: Naqvi Najam Abbas Dr. Li YanJun Space Academy,

A Stellar Gyroscope for CubeSat Attitude Determination

A Stellar Gyroscope for CubeSat Attitude Determination Samir A. Rawashdeh and James E. Lumpp, Jr. Space Systems Laboratory University of Kentucky James Barrington-Brown and Massimiliano Pastena SSBV Space

A Miniaturized Satellite Attitude Determination and Control System with Autonomous Calibration Capabilities

A Miniaturized Satellite Attitude Determination and Control System with Autonomous Calibration Capabilities Sanny Omar Dr. David Beale Dr. JM Wersinger Introduction ADACS designed for CubeSats CubeSats

Generation X. Attitude Control Systems (ACS) Aprille Ericsson Dave Olney Josephine San. July 27, 2000

Generation X Attitude Control Systems (ACS) Aprille Ericsson Dave Olney Josephine San July 27, 2000 ACS Overview Requirements Assumptions Disturbance Torque Assessment Component and Control Mode Recommendations

Integrated Test Facility for Nanosat Assessment and Verification

Integrated Test Facility for Nanosat Assessment and Verification Steve Wassom, Quinn Young, Bryan Bingham, Rees Fullmer, Mitch Whiteley, Robert Burt, Mike Watson, Tom Ortiz, Joe Richards, Sam Wilcox Utah

Attitude Determination and. Attitude Control

Attitude Determination and Placing the telescope in orbit is not the end of the story. It is necessary to point the telescope towards the selected targets, or to scan the selected sky area with the telescope.

Spinning Satellites Examples. ACS: Gravity Gradient. ACS: Single Spin

Attitude Determination and Attitude Control Placing the telescope in orbit is not the end of the story. It is necessary to point the telescope towards the selected targets, or to scan the selected sky

Quaternion-Based Tracking Control Law Design For Tracking Mode

A. M. Elbeltagy Egyptian Armed forces Conference on small satellites. 2016 Logan, Utah, USA Paper objectives Introduction Presentation Agenda Spacecraft combined nonlinear model Proposed RW nonlinear attitude

Attitude Control Strategy for HAUSAT-2 with Pitch Bias Momentum System

SSC06-VII-5 Attitude Control Strategy for HAUSAT-2 with Pitch Bias Momentum System Young-Keun Chang, Seok-Jin Kang, Byung-Hoon Lee, Jung-on Choi, Mi-Yeon Yun and Byoung-Young Moon School of Aerospace and

AN ATTITUDE DETERMINATION SYSTEM WITH MEMS GYROSCOPE DRIFT COMPENSATION FOR SMALL SATELLITES

University of Kentucky UKnowledge Theses and Dissertations--Electrical and Computer Engineering Electrical and Computer Engineering 2013 AN ATTITUDE DETERMINATION SYSTEM WITH MEMS GYROSCOPE DRIFT COMPENSATION

Sliding Mode Control Strategies for Spacecraft Rendezvous Maneuvers

Osaka University March 15, 2018 Sliding Mode Control Strategies for Spacecraft Rendezvous Maneuvers Elisabetta Punta CNR-IEIIT, Italy Problem Statement First Case Spacecraft Model Position Dynamics Attitude

Attitude Control of UWE-4 for Orbit Correction during Formation Flying

Attitude Control of UWE-4 for Orbit Correction during Formation Flying 1) By Siddharth DADHICH 1), Philip BANGERT 2) and Klaus SCHILLING 3) Department of Computer Science, Electrical and Space Engineering,

Spacecraft Subsystems Part 1 Fundamentals of Attitude Control

Spacecraft Subsystems Part 1 Fundamentals of Attitude Control by Michael A. Benoist, P.E. Contents 1. Introduction... 4 Reference Frames... 6 Representations... 7 Dynamics... 11 2. Determination Methods...

Spacecraft Attitude Dynamics for Undergraduates

Session 1123 Spacecraft Attitude Dynamics for Undergraduates Dr. Rachel Shinn Embry Riddle Aeronautical University, Prescott, AZ Abstract Teaching spacecraft attitude dynamics to undergraduate students

MAE 142 Homework #5 Due Friday, March 13, 2009

MAE 142 Homework #5 Due Friday, March 13, 2009 Please read through the entire homework set before beginning. Also, please label clearly your answers and summarize your findings as concisely as possible.

GP-B Attitude and Translation Control. John Mester Stanford University

GP-B Attitude and Translation Control John Mester Stanford University 1 The GP-B Challenge Gyroscope (G) 10 7 times better than best 'modeled' inertial navigation gyros Telescope (T) 10 3 times better

D-SAT Simplified Magnetic Attitude Control

D-SAT Simplified Magnetic Attitude Control Warren K. Soh, Norhizam Hamzah, Ahmad Sabirin Arshad Astronautic Technology (M) Sdn. Bhd. (ATSB) Suite G1A, Enterprise 3, Technology Park Malaysia, Bukit Jalil

The Torque Rudder: A Novel Semi-Passive Actuator for Small Spacecraft Attitude Control

The Torque Rudder: A Novel Semi-Passive Actuator for Small Spacecraft Attitude Control Grant Bonin, Vincent Tarantini, Luke Stras, and Robert E. Zee UTIAS Space Flight Laboratory Toronto, On. Canada M3H

Chapter 8 Part 1. Attitude Dynamics: Disturbance Torques AERO-423

Chapter 8 Part 1 Attitude Dynamics: Disturbance Torques AEO-43 Types of Disturbance Torques Solar Pressure Dominant torque for geosynchronous satellites Gravity Gradient Can be disturbance or control torque

Measurement p. 1 What Is Physics? p. 2 Measuring Things p. 2 The International System of Units p. 2 Changing Units p. 3 Length p. 4 Time p. 5 Mass p.

Measurement p. 1 What Is Physics? p. 2 Measuring Things p. 2 The International System of Units p. 2 Changing Units p. 3 Length p. 4 Time p. 5 Mass p. 7 Review & Summary p. 8 Problems p. 8 Motion Along

Development of an Active Magnetic Attitude Determination and Control System for Picosatellites on highly inclined circular Low Earth Orbits

Development of an Active Magnetic Attitude Determination and Control System for Picosatellites on highly inclined circular Low Earth Orbits A thesis submitted in fulfilment of the requirements for the

Spacecraft Bus / Platform

Spacecraft Bus / Platform Propulsion Thrusters ADCS: Attitude Determination and Control Subsystem Shield CDH: Command and Data Handling Subsystem Payload Communication Thermal Power Structure and Mechanisms

Fundamentals of High Accuracy Inertial Navigation Averil B. Chatfield Table of Contents

Navtech Part #2440 Preface Fundamentals of High Accuracy Inertial Navigation Averil B. Chatfield Table of Contents Chapter 1. Introduction...... 1 I. Forces Producing Motion.... 1 A. Gravitation......

Kinetic Energy of Rolling

Kinetic Energy of Rolling A solid disk and a hoop (with the same mass and radius) are released from rest and roll down a ramp from a height h. Which one is moving faster at the bottom of the ramp? A. they

FIBER OPTIC GYRO-BASED ATTITUDE DETERMINATION FOR HIGH- PERFORMANCE TARGET TRACKING

FIBER OPTIC GYRO-BASED ATTITUDE DETERMINATION FOR HIGH- PERFORMANCE TARGET TRACKING Elias F. Solorzano University of Toronto (Space Flight Laboratory) Toronto, ON (Canada) August 10 th, 2016 30 th AIAA/USU

A GRAVITY GRADIENT, MOMENTUM-BIASED ATTITUDE CONTROL SYSTEM FOR A CUBESAT. A Thesis. presented to

A GRAVITY GRADIENT, MOMENTUM-BIASED ATTITUDE CONTROL SYSTEM FOR A CUBESAT A Thesis presented to the Faculty of California Polytechnic State University, San Luis Obispo In Partial Fulfillment of the Requirements

Design of Attitude Determination and Control Subsystem

Design of Attitude Determination and Control Subsystem 1) Control Modes and Requirements Control Modes: Control Modes Explanation 1 ) Spin-Up Mode - Acquisition of Stability through spin-up maneuver -

Hysteresis Nutation Damper for Spin Satellite

Hysteresis Nutation Damper for Spin Satellite Hamed Shahmohamadi Ousaloo * Send Orders for Reprints to reprints@benthamscience.net The Open Aerospace Engineering Journal, 2013, 6, 1-5 1 Open Access Space

Attitude Control of a Bias Momentum Satellite Using Moment of Inertia

I. INTRODUCTION Attitude Control of a Bias Momentum Satellite Using Moment of Inertia HYOCHOONG BANG Korea Advanced Institute of Science and Technology HYUNG DON CHOI Korea Aerospace Research Institute

PHYSICS 220. Lecture 15. Textbook Sections Lecture 15 Purdue University, Physics 220 1

PHYSICS 220 Lecture 15 Angular Momentum Textbook Sections 9.3 9.6 Lecture 15 Purdue University, Physics 220 1 Last Lecture Overview Torque = Force that causes rotation τ = F r sin θ Work done by torque

AIR FORCE INSTITUTE OF TECHNOLOGY

A NUMERICAL ANALYSIS OF PASSIVE ATTITUDE STABILIZATION USING A TETHERED BALLOON ON A GRAVITY GRADIENT SATELLITE THESIS Ernest Matias Maramba, Second Lieutenant, USAF AFIT/GA/ENY/05-M07 DEPARTMENT OF THE

2007 Problem Topic Comment 1 Kinematics Position-time equation Kinematics 7 2 Kinematics Velocity-time graph Dynamics 6 3 Kinematics Average velocity

2007 Problem Topic Comment 1 Kinematics Position-time equation Kinematics 7 2 Kinematics Velocity-time graph Dynamics 6 3 Kinematics Average velocity Energy 7 4 Kinematics Free fall Collisions 3 5 Dynamics

An Inverse Dynamics Attitude Control System with Autonomous Calibration. Sanny Omar Dr. David Beale Dr. JM Wersinger

An Inverse Dynamics Attitude Control System with Autonomous Calibration Sanny Omar Dr. David Beale Dr. JM Wersinger Outline Attitude Determination and Control Systems (ADACS) Overview Coordinate Frames

UNIVERSITY OF OSLO Department of Physics. Attitude Control of a Nano Satellite. Master thesis. Fredrik Stray

UNIVERSITY OF OSLO Department of Physics Attitude Control of a Nano Satellite Master thesis Fredrik Stray October 1, 21 Preface This master thesis is part of the fulfillment of the Master of Science in

PRELIMINARY HARDWARE DESIGN OF ATTITUDE CONTROL SUBSYSTEM OF LEONIDAS SPACECRAFT

PRELIMINARY HARDWARE DESIGN OF ATTITUDE CONTROL SUBSYSTEM OF LEONIDAS SPACECRAFT Chak Shing Jackie Chan College of Engineering University of Hawai i at Mānoa Honolulu, HI 96822 ABSTRACT In order to monitor

Simulation Results of Alternative Methods for Formation Separation Control

Simulation Results of Alternative Methods for Formation Separation Control Thomas Heine, Charles Bussy-Virat, Mark Moldwin, Aaron Ridley Department of Climate and Space Sciences and Engineering University

On the satellite s electrodynamic attitude stabilization

On the satellite s electrodynamic attitude stabilization Alexander Yu. Aleksandrov Kirill A. Antipov Alexey A. Tikhonov aatikhonov@rambler.ru Abstract The paper deals with a satellite in a circular near-earth

Precision Attitude and Translation Control Design and Optimization

Precision Attitude and Translation Control Design and Optimization John Mester and Saps Buchman Hansen Experimental Physics Laboratory, Stanford University, Stanford, California, U.S.A. Abstract Future

Jitter and Basic Requirements of the Reaction Wheel Assembly in the Attitude Control System

Jitter and Basic Requirements of the Reaction Wheel Assembly in the Attitude Control System Lulu Liu August, 7 1 Brief Introduction Photometric precision is a major concern in this space mission. A pointing

Satellite Dynamics Simulator Development Using Lie Group Variational Integrator

Satellite Dynamics Simulator Development Using Lie Group Variational Integrator Daeyoung Lee, John C. Springmann, and Sara C. Spangelo and James W. Cutler Aerospace Engineering, University of Michigan,

Attitude Control on the Pico Satellite Solar Cell Testbed-2

SSC12-II-1 Attitude Control on the Pico Satellite Solar Cell Testbed-2 Siegfried W. Janson, Brian S. Hardy, Andrew Y. Chin, Daniel L. Rumsey, Daniel A. Ehrlich, and David A. Hinkley The Aerospace Corporation

From an experimental idea to a satellite

From an experimental idea to a satellite Hansjörg Dittus Institute of Space Systems, Bremen German Aerospace Center Looking back in History Yukawa potential Gravity at large scales Weak gravity Nordtvedt

CHAPTER 4 CONVENTIONAL CONTROL FOR SATELLITE ATTITUDE

93 CHAPTER 4 CONVENTIONAL CONTROL FOR SATELLITE ATTITUDE 4.1 INTRODUCTION Attitude control is the process of achieving and maintaining an orientation in space. The orientation control of a rigid body has

5/6/2018. Rolling Without Slipping. Rolling Without Slipping. QuickCheck 12.10

Rolling Without Slipping Rolling is a combination of rotation and translation. For an object that rolls without slipping, the translation of the center of mass is related to the angular velocity by Slide

Sail-Assisted End-of-Life Disposal of High-LEO Satellites

4th International Symposium on Solar Sailing Kyoto, Japan, January 17-20, 2017 Sail-Assisted End-of-Life Disposal of High-LEO Satellites Sergey Trofimov Keldysh Institute of Applied Mathematics Russian

3D Pendulum Experimental Setup for Earth-based Testing of the Attitude Dynamics of an Orbiting Spacecraft

3D Pendulum Experimental Setup for Earth-based Testing of the Attitude Dynamics of an Orbiting Spacecraft Mario A. Santillo, Nalin A. Chaturvedi, N. Harris McClamroch, Dennis S. Bernstein Department of

Spacecraft Dynamics and Control

Spacecraft Dynamics and Control Matthew M. Peet Arizona State University Lecture 1: In the Beginning Introduction to Spacecraft Dynamics Overview of Course Objectives Determining Orbital Elements Know

Attitude Determination and Control System Design for STU-2A Cubesat and In-Orbit Results

13 th Annual Summer CubeSat Developer s Workshop August 6-7, 2016, Logan, Utah Attitude Determination and Control System Design for STU-2A Cubesat and In-Orbit Results Presented by Shufan Wu Guowen Sun,

Attitude Determination and Control Subsystem (ADCS) Review

Attitude Determination and Control Subsystem (ADCS) Review Contents Attitude Determination and Control Subsystem (ADCS) Function Impact of Mission Requirements and Other Subsystems on ADCS ADCS Design

An optimum magnetic control torque generation of a momentum bias satellite

Int. Jnl. of Multiphysics Volume 8 Number 4 69 An optimum magnetic control torque generation of a momentum bias satellite Nurulasikin Mohd Suhadis, *, Renuganth Varatharajoo School of Aerospace Engineering,

ATTITUDE CONTROL MECHANIZATION TO DE-ORBIT SATELLITES USING SOLAR SAILS

IAA-AAS-DyCoSS2-14-07-02 ATTITUDE CONTROL MECHANIZATION TO DE-ORBIT SATELLITES USING SOLAR SAILS Ozan Tekinalp, * Omer Atas INTRODUCTION Utilization of solar sails for the de-orbiting of satellites is

Attitude Control Simulator for the Small Satellite and Its Validation by On-orbit Data of QSAT-EOS

SSC17-P1-17 Attitude Control Simulator for the Small Satellite and Its Validation by On-orbit Data of QSAT-EOS Masayuki Katayama, Yuta Suzaki Mitsubishi Precision Company Limited 345 Kamikmachiya, Kamakura

AIR FORCE INSTITUTE OF TECHNOLOGY

OPTIMAL SPACECRAFT ATTITUDE CONTROL USING AERODYNAMIC TORQUES THESIS Michael Luke Gargasz, Captain, USAF AFIT/GA/ENY/07-M08 DEPARTMENT OF THE AIR FORCE AIR UNIVERSITY AIR FORCE INSTITUTE OF TECHNOLOGY

General Definition of Torque, final. Lever Arm. General Definition of Torque 7/29/2010. Units of Chapter 10

Units of Chapter 10 Determining Moments of Inertia Rotational Kinetic Energy Rotational Plus Translational Motion; Rolling Why Does a Rolling Sphere Slow Down? General Definition of Torque, final Taking

INTERNAL THALES ALENIA SPACE

Workshop Galileo Galilei (GG) and GGG lab prototype: state of the art and new possibilities Template reference : 100181670S-EN GG error budget from the end-to-end simulator developed at TAS-I Giuseppe

Satellite Components & Systems. Dr. Ugur GUVEN Aerospace Engineer (P.hD) Nuclear Science & Technology Engineer (M.Sc)

Satellite Components & Systems Dr. Ugur GUVEN Aerospace Engineer (P.hD) Nuclear Science & Technology Engineer (M.Sc) Definitions Attitude: The way the satellite is inclined toward Earth at a certain inclination

Simplified Analytical Model of a Six-Degree-of-Freedom Large-Gap Magnetic Suspension System

NASA Technical Memorandum 112868 Simplified Analytical Model of a Six-Degree-of-Freedom Large-Gap Magnetic Suspension System Nelson J. Groom Langley Research Center, Hampton, Virginia June 1997 National

DYNAMIC ANALYSIS OF SPACE TETHER MISSIONS

DYNAMIC ANALYSIS OF SPACE TETHER MISSIONS Volume 126 ADVANCES IN THE ASTRONAUTICAL SCIENCES by Eu gene M. Levin Published for the American Astronautical Society by Univelt, Incorporated, P.O. Box 28130,

EXAMPLE: MODELING THE PT326 PROCESS TRAINER

CHAPTER 1 By Radu Muresan University of Guelph Page 1 EXAMPLE: MODELING THE PT326 PROCESS TRAINER The PT326 apparatus models common industrial situations in which temperature control is required in the

III. Work and Energy

Rotation I. Kinematics - Angular analogs II. III. IV. Dynamics - Torque and Rotational Inertia Work and Energy Angular Momentum - Bodies and particles V. Elliptical Orbits The student will be able to:

Attitude Stabilization for CubeSat

Attitude Stabilization for CubeSat Attitude Stabilization for CubeSat: Concepts and Technology By Mohammed Chessab Mahdi Proofreading By Nicholas Arthur Hall Attitude Stabilization for CubeSat: Concepts

Space mission environments: sources for loading and structural requirements

Space structures Space mission environments: sources for loading and structural requirements Prof. P. Gaudenzi Università di Roma La Sapienza, Rome Italy paolo.gaudenzi@uniroma1.it 1 THE STRUCTURAL SYSTEM

Chapter 6: Momentum Analysis

6-1 Introduction 6-2Newton s Law and Conservation of Momentum 6-3 Choosing a Control Volume 6-4 Forces Acting on a Control Volume 6-5Linear Momentum Equation 6-6 Angular Momentum 6-7 The Second Law of

Chapter 1. Introduction

Chapter 1 Introduction Vehicle dynamics and control is a rich subject involving a variety of topics from mechanics and control theory. In a first course in dynamics, students learn that the motion of a

IMPLEMENTATION OF A DECOUPLED CONTROLLER ELECTROMAGNETS MOUNTED IN A PLANAR ARRAY. NASA Langley Research Center. Hampton, VA.

IMPLEMENTATION OF A DECOUPLED CONTROLLER FOR A MAGNETIC SUSPENSION SYSTEM USING ELECTROMAGNETS MOUNTED IN A PLANAR ARRAY D. E. Cox N. J. Groom NASA Langley Research Center Hampton, VA Abstract An implementation

Chapter 8: Momentum, Impulse, & Collisions. Newton s second law in terms of momentum:

linear momentum: Chapter 8: Momentum, Impulse, & Collisions Newton s second law in terms of momentum: impulse: Under what SPECIFIC condition is linear momentum conserved? (The answer does not involve collisions.)

Asteroid Impact Mission AIM Workshop. Electric Propulsion for Attitude & Orbit Control

Asteroid Impact Mission AIM Workshop Electric Propulsion for Attitude & Orbit Control ESA, ESTEC, Noordwijk, The Netherlands, 22-23 February 2016 Christophe R. Koppel Consulting Ind., 75008 Paris, France

CHAPTER 5 FUZZY LOGIC FOR ATTITUDE CONTROL

104 CHAPTER 5 FUZZY LOGIC FOR ATTITUDE CONTROL 5.1 INTRODUCTION Fuzzy control is one of the most active areas of research in the application of fuzzy set theory, especially in complex control tasks, which

A Multi-mode Attitude Determination and Control System for SUNSAT

A Multi-mode Attitude Determination and Control System for SUNSA Dr. Herman Steyn Department of Electronic Engineering, University of Stellenbosch Stellenbosch 76, South Africa el: +2721-88449, Fax: +2721-884981,

Analytical Mechanics. of Space Systems. tfa AA. Hanspeter Schaub. College Station, Texas. University of Colorado Boulder, Colorado.

Analytical Mechanics of Space Systems Third Edition Hanspeter Schaub University of Colorado Boulder, Colorado John L. Junkins Texas A&M University College Station, Texas AIM EDUCATION SERIES Joseph A.

Experimental Analysis of Low Earth Orbit Satellites due to Atmospheric Perturbations

Experimental Analysis of Low Earth Orbit Satellites due to Atmospheric Perturbations Aman Saluja #1, Manish Bansal #2, M Raja #3, Mohd Maaz #4 #Aerospace Department, University of Petroleum and Energy

An Attitude Control System and Commissioning Results of the SNAP-1 Nanosatellite

An Attitude Control System and Commissioning Results of the SNAP-1 Nanosatellite WH Steyn, Y Hashida and V Lappas Surrey Space Centre University of Surrey Guildford, Surrey GU2 5XH United Kingdom Abstract.

6-1. Conservation law of mechanical energy

6-1. Conservation law of mechanical energy 1. Purpose Investigate the mechanical energy conservation law and energy loss, by studying the kinetic and rotational energy of a marble wheel that is moving

Infrared Earth Horizon Sensors for CubeSat Attitude Determination

Infrared Earth Horizon Sensors for CubeSat Attitude Determination Tam Nguyen Department of Aeronautics and Astronautics Massachusetts Institute of Technology Outline Background and objectives Nadir vector

1 of 7 4/5/2010 10:25 PM Name Date UNIT 3 TEST 1. In the formula F = Gm m /r, the quantity G: depends on the local value of g is used only when Earth is one of the two masses is greatest at the surface

c 2009 John Gregory Warner

c 2009 John Gregory Warner ATTITUDE DETERMINATION AND CONTROL OF NANO-SATELLITES BY JOHN GREGORY WARNER THESIS Submitted in partial fulfillment of the requirements for the degree of Master of Science in

SATELLITE ATTITUDE TRACKING BY QUATERNION-BASED BACKSTEPPING. Raymond Kristiansen,1 Per Johan Nicklasson,2 Jan Tommy Gravdahl,3

SATELLITE ATTITUDE TRACKING BY QUATERNION-BASED BACKSTEPPING Raymond Kristiansen,1 Per Johan Nicklasson,2 Jan Tommy Gravdahl,3 Department of Space Technology Narvik University College, Norway Department

Gravity Probe B Data Analysis Challenges, Insights, and Results

Gravity Probe B Data Analysis Challenges, Insights, and Results Mac Keiser April 15, 27 April 15, 27 Jacksonville, FL 1 Topics Data Analysis Strategy and Methods Challenges and Insights Trapped Magnetic

Rotational Dynamics. A wrench floats weightlessly in space. It is subjected to two forces of equal and opposite magnitude: Will the wrench accelerate?

Rotational Dynamics A wrench floats weightlessly in space. It is subjected to two forces of equal and opposite magnitude: Will the wrench accelerate? A. yes B. no C. kind of? Rotational Dynamics 10.1-3

STATICS Chapter 1 Introductory Concepts

Contents Preface to Adapted Edition... (v) Preface to Third Edition... (vii) List of Symbols and Abbreviations... (xi) PART - I STATICS Chapter 1 Introductory Concepts 1-1 Scope of Mechanics... 1 1-2 Preview

AP Physics 1. Course Overview

Radnor High School Course Syllabus AP Physics 1 Credits: Grade Weighting: Yes Prerequisites: Co-requisites: Length: Format: 1.0 Credit, weighted Honors chemistry or Advanced Chemistry Honors Pre-calculus

COUPLED ORBITAL AND ATTITUDE CONTROL SIMULATION

COUPLED ORBITAL AND ATTITUDE CONTROL SIMULATION Scott E. Lennox AOE 5984: Advanced Attitude Spacecraft Dynamics and Control December 12, 23 INTRODUCTION In the last few years the space industry has started

AP Physics C Syllabus

Course Overview AP Physics C Syllabus AP Physics C will meet for 90 minutes on block scheduling and for 45 minutes on regular scheduling. Class activities will include lecture, demonstration, problem solving

7. The gyroscope. 7.1 Introduction. 7.2 Theory. a) The gyroscope

K 7. The gyroscope 7.1 Introduction This experiment concerns a special type of motion of a gyroscope, called precession. From the angular frequency of the precession, the moment of inertia of the spinning

IAC-18-E Enhanced Attitude Stability and Control for CubeSats by Real-Time On-Orbit Determination of Their Dynamic Magnetic Moment

IAC-18-E2.4.1 Enhanced Attitude Stability and Control for CubeSats by Real-Time On-Orbit Determination of Their Dynamic Magnetic Moment Abdelmadjid Lassakeur*, Craig Underwood, Benjamin Taylor Surrey Space

PHYSICS. Course Structure. Unit Topics Marks. Physical World and Measurement. 1 Physical World. 2 Units and Measurements.

PHYSICS Course Structure Unit Topics Marks I Physical World and Measurement 1 Physical World 2 Units and Measurements II Kinematics 3 Motion in a Straight Line 23 4 Motion in a Plane III Laws of Motion

Flux-Pinned Interfaces for the Assembly, Manipulation, and Reconfiguration of Modular Space Systems

Flux-Pinned Interfaces for the Assembly, Manipulation, and Reconfiguration of Modular Space Systems Joseph P. Shoer 1 Cornell University, Ithaca, NY, 14853 Action-at-a-distance interactions between permanent

Attitude Determination using Infrared Earth Horizon Sensors

SSC14-VIII-3 Attitude Determination using Infrared Earth Horizon Sensors Tam Nguyen Department of Aeronautics and Astronautics, Massachusetts Institute of Technology 77 Massachusetts Avenue, Cambridge,

5.12 The Aerodynamic Assist Trajectories of Vehicles Propelled by Solar Radiation Pressure References...

1 The Two-Body Problem... 1 1.1 Position of the Problem... 1 1.2 The Conic Sections and Their Geometrical Properties... 12 1.3 The Elliptic Orbits... 20 1.4 The Hyperbolic and Parabolic Trajectories...

ENAE483: Principles of Space System Design Power Propulsion Thermal System

Power Propulsion Thermal System Team B4: Ben Abresch Jason Burr Kevin Lee Scott Wingate November 8th, 2012 Presentation Overview Mission Guidelines Project Specifications Initial Design Power Thermal Insulation

Hybrid spacecraft attitude control system

Int. Jnl. of Multiphysics Volume 1 Number 2 2007 221 Hybrid spacecraft attitude control system Renuganth Varatharajoo *, Ramly Ajir, Tamizi Ahmad Department of Aerospace Engineering, University Putra Malaysia,