Optimal scheduling for satellite refueling in circular orbits

Shen, Haijun

05 1900

No description available.

Artificial satellites Orbits

A collaborative optimization approach to improve the design and deployment of satellite constellations

Budianto, Irene Arianti

12 1900

No description available.

Artificial satellites Launching

An attitude and orbit determination and control system for a small geostationary satellite /

Thopil, G. A.

January 2006

Thesis (MScIng)--University of Stellenbosch, 2006. / Bibliography. Also available via the Internet.

An investigation of the fine-pointing control system of a soft-gimbaled orbiting telescope /

Morrell, Frederick R.

January 1970

Thesis (M.S. in Electrical Engineering)--University of Virginia, March 1968. / "June 1970." Submitted in partial fulfillment of the requirements for the degree Master of Electrical Engineering, University of Virginia, Charlottesville, Virginia, March 1968.--Report documentation page. "NASA TN D-5829." "L-6988." Includes bibliographical references (p. 17). Also available online in PDF from NASA Technical Reports Server Web site.

Command generation for tethered satellite systems

Robertson, Michael James,

January 2004

Thesis (Ph.D.)--School of Mechanical Engineering, Georgia Institute of Technology, 2005. / Singhose, William, Committee Chair ; Banerjee, Arun, Committee Member ; Chen, Ye-Hwa, Committee Member ; Ebert-Uphoff, Imme, Committee Member ; Olds, John, Committee Member. Includes bibliographical references.

Analysis and design of the mechanical systems onboard a microsatellite in low-earth orbit an assessment study /

Solomon, Dylan Raymond.

January 2005

Thesis (M.S.)--Montana State University--Bozeman, 2005. / Typescript. Chairperson, Graduate Committee: David M. Klumpar. Includes bibliographical references (leaves 220-221).

EXTENDED ORBITAL FLIGHT OF A CUBESAT IN THE LOWER THERMOSPHERE WITH ACTIVE ATTITUDE CONTROL

Moorthy, Ananthalakshmy Krishna

03 July 2019

A wide variety of scientifically interesting missions could be enabled by orbital flight altitudes of 150 – 250 km. For the present work, this range of altitudes is defined as extremely Low Earth Orbit (eLEO). The use of low-cost nanosatellites (mass < 10 kg) has reduced the cost barrier to orbital flight over the last decade and the present study investigates the feasibility of using primarily commercial, off-the-shelf (COTS) hardware to build a nanosat specifically to allow extended mission times in eLEO. CubeSats flying in the lower thermosphere have the potential to enable close monitoring of the Earth’s surface for scientific, commercial, and defense-related missions. The results of this research show that the proper selection of primary and attitude control thrusters combined with precise control techniques result in significant extension of the orbital life of a CubeSat in eLEO, thus allowing detailed explorations of the atmosphere. In this study, the orbit maintenance controller is designed to maintain a mission-averaged, mean altitude of 244 km. An estimate is made of the primary disturbance torque due to aerodynamic drag using a high-fidelity calculation of the rarefied gas drag based on a Direct Simulation, Monte-Carlo simulation. The primary propulsion system consists of a pair of electrospray thrusters providing a combined thrust of 0.12 mN at 1 W. Results of a trade study to select the best attitude control option indicate pulsed plasma thrusters operating at 1 W are preferable to reaction wheels or mangetorquers at the selected altitude. An extended Kalman filter is used for orbital position and spacecraft attitude estimations. The attitude determination system consists of sun sensors, magnetometers, gyroscopes serving as attitude sensors. The mission consists of two phases. In Phase I, a 4U CubeSat is deployed from a 414 km orbit and uses the primary propulsion system to deorbit to an initial altitude within the targeted range of 244 +/- 10 km. Phase I lasts 12.73 days with the propulsion system consuming 5.6 g of propellant to deliver a ∆V of 28.12 m/s. In Phase II the mission is maintained until the remaining 25.2 g of propellant is consumed. Phase II lasts for 30.27 days, corresponding to a ∆V of 57.22 m/s with a mean altitude of 244 km. The mean altitude for an individual orbit over the entire mission was found to vary from a maximum of 252 km to a minimum of 236 km. Using this approach, a primary mission life of 30.27 days could be achieved, compared with 3.1 days without primary propulsion.

Conflict of interests : the ideas, interests and institutions involved in the development of Canadian satellite policy from 1960-1980

Marston, Wendy

January 1991

No description available.

Artificial satellites

The tone sense multiaccess protocol with partial collision detection (TSMA/PCD) for packet satellite communications.

January 1987

by Lo Man Keung. / Abstract in Chinese and English. / Thesis (M.Ph.)--Chinese University of Hong Kong, 1987. / Bibliography: leaves 80-81.

Delay minimization for packet satellite communication systems.

January 1990

Wong, Wing-ming Eric. / Thesis (M.Phil.)--Chinese University of Hong Kong, 1990. / Bibliography: leaves 46-47. / ACKNOWLEDGMENTS / ABSTRACT / Chapter Chapter 1 --- INTRODUCTION --- p.1 / Chapter 1.1 --- Advantages and Disadvantages --- p.1 / Chapter 1.2 --- Satellite System Engineering --- p.2 / Chapter 1.3 --- Channel Allocation Methods --- p.3 / Chapter 1.4 --- Outline of this Thesis --- p.5 / Chapter Chapter 2 --- DELAY BOUNDS --- p.6 / Chapter 2.1 --- Introduction --- p.6 / Chapter 2.2 --- The Packet Satellite System --- p.7 / Chapter 2.3 --- The Idealized Protocol with Contention-Free Reservation --- p.8 / Chapter 2.4 --- Delay Lower Bound for Protocols with Contention-Free Reservation --- p.9 / Chapter 2.5 --- Delay Lower Bound for Protocols with Contention-Based Reservation --- p.14 / Chapter Chapter 3 --- IN SEARCH OF A MINIMUM DELAY PROTOCOL --- p.23 / Chapter 3.1 --- Introduction --- p.23 / Chapter 3.2 --- The Packet Satellite System --- p.25 / Chapter 3.3 --- The Transmission Protocol --- p.26 / Chapter 3.4 --- Throughput Analysis --- p.27 / Chapter 3.5 --- Delay Analysis --- p.28 / Chapter 3.6 --- Minimization of DI --- p.31 / Chapter 3.7 --- Minimization of DII --- p.38 / Chapter 3.8 --- Numerical Examples --- p.38 / Chapter Chapter 4 --- CONCLUSIONS --- p.45 / REFERENCES --- p.46 / APPENDIX --- p.48