The Naval Postgraduate School SCAT++ CubeSat Program (original) (raw)

FFF NPS SCAT Systems Engineering and Payload

The Naval Postgraduate School's first CubeSat, the NPS Solar Cell Array Tester (NPS-SCAT), demonstrates the capability of the CubeSat form factor as a technology test bed by implementing a single experiment-a solar cell tester. The need to validate solar cell performance on orbit, in the harsh space environment, is recurring with the continued development of advanced, untested solar cells. By using a relatively inexpensive platform, the CubeSat, such solar cells can be tested and the risk for larger satellites mitigated with this experiment. This thesis discusses the design and construction process of the solar cell array tester payload along with its integration with the remaining satellite subsystems (command and data handling subsystem, communications subsystem, and electrical power subsystem) including the problems encountered along the way and the chosen solutions. In addition, the systems engineering and testing procedures developed for and conducted on the satellite engineering design unit will be described in detail. 15. NUMBER OF PAGES 190

NPS-SCAT: Systems Engineering and Payload Subsystem Design, Integration, and Testing of NPS' First CubeSat

2010

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Design Progress in the Satellite Quick Research Testbed (SQUIRT) Program

1995

Stanford University's Satellite Systems Development Laboratory (SSDL) is achieving positive results in its yearly educational program known as the Satellite Quick Research Testbed (SQUIRT). This project's goal is to produce student engineered microspacecraft capable of servicing state-of-the-art research payloads. SQUIRT spacecraft are about 25 pounds, 18 inches in diameter, nine inches tall, and have a cash budget for parts of approximately $50,000. After 18 months of work, the first SQUIRT design team is in the fmal assembly and test stage of the Stanford Audio Phonic Photographic Infrared Experiment (SAPPHIRE) satellite. This microspacecraft will be used to space characterize experimental infrared sensors as well as to perform digital photography and broadcast voice synthesized messages. A second SQUIRT team has initiated the detailed design of the Orbiting Picosatellite Automated Launcher (OPAL) satellite. This microspacecraft will study the feasibility of repeatedly deploying hockey puck sized science craft for research purposes. In addition, several commercial offthe-shelf (COTS) sensors are being flown in order to assess their performance in the space environment. This paper discusses developmental efforts within the SQUIRT program, the design progress of the current SQUIRT vehicles, and future payload concepts and program initiatives. The SQUIRT Program Based on a vocal industry demand for realistic education in space systems engineering, '" Ph.D. Candidate, Department of Mechanical Engineering, Design Division. Systems Engineer, Caelum Research Corporation, NASA Ames. AIAA Student Member.

Design of a University Nano-Satellite: the PiCPoT Case

IEEE Transactions on Aerospace and Electronic Systems, 2000

Satellites are not necessarily something huge and expensive. Small satellites have been designed (or are being designed) by several universities. These satellites must fit within tight cost constraints, for the launch and the actual satellite hardware. Success in developing these satellites, and the related technologies and methods, would enable an easier access to space, especially for SMEs, leading to new markets and applications.

Lessons from the Inaugural Satellite Design Challenge

Proceedings of the Canadian Engineering Education Association, 2013

The inaugural Canadian Satellite Design Challenge provided many experiential learning opportunities for students through the design, implementation, and testing of the T-Sat1 nanosatellite.The University of Manitoba team elected to build all components from the ground up in order to develop many technical and non-technical skills that complement the classroom experience.The first phases of the project focused on the definition of requirements, specifications, and interfaces. Then, the team began prototyping, implementing, and integrating subsystems. Finally, the spacecraft was tested at the Canadian Space Agency laboratories in Ottawa and obtained second place overall in the competition.This paper describes some of the major lessons from the implementation, integration, and testing phases of the project. In addition, some insight is provided as to the ongoing changes for the second iteration of the competition that aim at improving the experience and performance of the satellite.

The 75 Student’s Satellite’s Mission - Engineering of CubeSats

medium platform, 2023

“Let us aspire to conduct more spectacular space missions in future years” Prepare to witness history in the making with the 75SSM program — a meticulously crafted initiative of Indian academia that will deploy an impressive fleet of 75 student-built satellites into low Earth orbit (LEO). This groundbreaking program pushes the boundaries of what’s possible in space exploration with cutting-edge technology and unprecedented student involvement. The 75SSM expedition is poised to be a remarkable achievement, ushering in a new era of space research and innovation.

CubeSat: The Pico-Satellite Standard for Research and Education

AIAA SPACE 2008 Conference & Exposition, 2008

The development of the CubeSat standard, a picosatellite standard, has become a tool that encourages engineering collaboration, trains students with real-world satellite experience, and provides technology advancement in the aerospace industry. The Poly-Picosatellite Orbital Deployer (P-POD), in conjuction with the CubeSat standard, plays a key role in providing access to space for CubeSats. Developing satellites at the CubeSat level highlight the increasing opportunities for access to space while yielding quicker development times.

The Parasat Space Flight Program

1999

The ParaSat program, a new university- based satellite development initiative, is described. The goal of this program is to produce student managed and engineered satellites capable of supporting both education and research. Educationally, these projects expose students to the following: 1) a range of subsystem technologies necessary to develop such a spacecraft, 2) a range of lifecycle phases including conception, fabrication, and test, and 3) a realistic design team environment that includes the satisfaction of a principal investigator, the rational defense of design choices, and involvement in a team enterprise. From a research perspective, the resulting spacecraft provide inexpensive and rapidly developed platforms for space based research and/or technology demonstration; these platforms, however, are limited in capability and have a lower than normal reliability. Compared to existing academic satellite development programs, the ParaSat program has been designed to operate with ...

Simulation of the deployment and orbit operations of the NPS-SCAT CubeSat

The Naval Postgraduate School SCAT++ CubeSat Program (original) (raw)

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